MiR-193b-365, a brown fat enriched microRNA cluster, is
essential for brown fat differentiation
Lei Sun1,8, Huangming Xie1,3,6,8, Marcelo A Mori5, Ryan Alexander1,7, Bingbing Yuan1,
Shilpa M. Hattangadi1,4, Qingqing Liu1, C. Ronald Kahn5, and Harvey F. Lodish1,2,7,9
1 Whitehead Institute for Biomedical Research, 9 Cambridge Center, Cambridge, MA 02142, USA
2 Department of Biological Engineering, Massachusetts Institute of Technology, Cambridge, MA
02139, USA
3 Computation and Systems Biology, Singapore-MIT Alliance, National University of Singapore, 4
Engineering Drive 3, Singapore 117576
4 Department of Hematology, Boston Children?s Hospital, Boston, MA 02115
5 Section on Integrative Physiology and Metabolism, Research Division, Joslin Diabetes Center,
Harvard Medical School, Boston, Massachusetts, USA
7 Department of Biology, Massachusetts Institute of Technology, Cambridge, MA 02139, USA
Abstract
Mammals have two principal types of fat. White adipose tissue (WAT) primarily serves to store
extra energy as triglycerides, while brown adipose tissue (BAT) is specialized to burn lipids for
heat generation and energy expenditure as a defense against cold and obesity 1, 2. Recent studies
demonstrate that brown adipocytes arise in vivo from a Myf5-positive, myoblastic progenitor by
the action of Prdm16 (PR domain containing 16). Here, we identified a brown fat-enriched
miRNA cluster, miR-193b-365, as a key regulator of brown fat development. Blocking miR-193b
and/or miR-365 in primary brown preadipocytes dramatically impaired brown adipocyte
adipogenesis by enhancing Runx1t1 (runt-related transcription factor 1; translocated to, 1)
expression whereas myogenic markers were significantly induced. Forced expression of miR-193b
and/or miR-365 in C2C12 myoblasts blocked the entire program of myogenesis, and, in
adipogenic condition, miR-193b induced myoblasts to differentiate into brown adipocytes.
MiR-193b-365 was upregulated by Prdm16 partially through Ppar?. Our results demonstrate that
miR-193b-365 serves as an essential regulator for brown fat differentiation, in part by repressing
myogenesis.
9Correspondence: Whitehead Institute for Biomedical Research, 9 Cambridge Center, Cambridge, MA 02142, USA; Tel: 617 258
5216; Fax: 617 258 6768; lodish@wi.mit.edu.6
Present address: Division of Newborn Medicine, Department of Medicine, Children?s Hospital Boston, 300 Longwood Avenue,
Boston, MA 02115, USA8
These authors contributed equally to this work.
AUTHOR CONTRIBUTIONS
L.S, H.X and H.F.L conceived the project and designed the experiments. L.S, H.X, M.A.M, R.A, B.Y, S.M.H and Q.L performed the
experiments. All authors analyzed data. L.S, H.X, M.A.M, H.F.L wrote the manuscript. C.R.K and H.F.L supervised the project.
COMPETING GINANCIAL INTERESTS
The authors declare no financial conflict of interest.
Accession number:
E-MEXP-2553; GSE27614
NIH Public Access
Author Manuscript
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
Published in final edited form as:
Nat Cell Biol. ; 13(8): 958?965. doi:10.1038/ncb2286.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
Keywords
miR-193; miR-365; miR-193b-365; microRNA; brown fat; brown adipocyte; lineage
determination; adipogenesis; myogenesis; Prdm16
Although the amount of BAT in human adults was previously thought to be minimal, recent
studies demonstrated that adult humans have substantial amounts of functioning BAT 3?5,
which inversely correlates with BMI and positively correlates with resting metabolic rate 3.
Loss of BAT activity may contribute to obesity and development of insulin resistance. When
BAT is genetically or surgically ablated, mice develop hyperphagia and obesity 6?8. Mice
deficient of Ucp1 (Uncoupling Protein 1), the hallmark of brown fat, are more susceptible to
diet-induced obesity and develop obesity at thermoneutrality even when they are fed a
control diet 9. Conversely, expression of Ucp1 in white adipocytes promotes energy
expenditure and prevents the development of dietary and genetic obesity 10, 11. In addition,
Bartelt. et al. demonstrated that brown fat is a major organ for triglyceride clearance 12.
Therefore, understanding the mechanisms controlling the development of BAT may provide
new therapeutic strategies for obesity and related disorders. Although, for decades, it was
believed that brown adipocytes and white adipocytes share a common progenitor, a lineage
tracing study demonstrated that brown adipocytes arise from a Myf5-positive, myoblastic
lineage 13. Prdm16 is a key regulator that controls the switch between brown fat and muscle
lineage. Ectopic expression of Prdm16 together with CEBP? can induce a functional BAT
program in myoblasts and skin fibroblasts 14. Knockdown of Prdm16 in brown
preadipocytes causes an induction of skeletal myogenesis 13. However, other factors that
regulate the switch between BAT and skeletal muscle remain unknown. Here, we show that
the miR-193b-365 cluster is important for lineage determination of brown adipocytes.
To uncover miRNAs that are important for brown fat lineage determination, we first
identified lineage-enriched miRNAs by comparing the genome-wide miRNA expression
patterns of mouse epididymal WAT, interscapular BAT and skeletal muscle using miRNA
microarrays. Based on the criteria described in Methods, 91 miRNAs were expressed in at
least one sample and differentially expressed between the three tissues (Fig. 1a and Fig.
S1a). Among BAT-enriched miRNAs, miR-193b and miR-365 were particularly interesting,
since they are co-located on chromosome 16 as a ~5kb cluster (Fig. S1b), suggesting that
they are a bicistronic transcript.
Cap-analysis gene expression (CAGE) Basic and Analysis Databases store original results
produced by CAGE-seq which measures expression levels of transcription starting sites by
sequencing large numbers of 5? transcript ends, termed CAGE tags 15, 16. We examined the
distribution of CAGE tags surrounding the miR-193b and miR-365-1 genes, and found that
there was no CAGE tag between miR-193b and miR-365-1 in the direction of transcription
(Fig. S1b). Furthermore, we designed 14 pairs of primers across the genomic region of
miR-193b-365, and performed RT-PCR to detect the primary transcripts of overlapping
segments of the miR-193b-365 gene (Supplementary Fig. S1c). The amplified fragments
covered the entire region between miR-193b and miR-365. Together, these data strongly
suggest that miR-193b-365 is a co-transcribed miRNA cluster.
We performed real-time PCR to examine the expression of miR-193b and miR-365 in 14
adult mouse tissues (Fig. 1b); both miRNAs were enriched in BAT. We measured their
expression levels at different time points during brown adipocyte differentiation of stromal-
vascular fraction (SVF) cells from interscapular brown fat (Fig. 1c). Both miRNAs showed
significant up-regulation during adipogenesis, ~5-fold for miR-193b and ~4-fold for
miR-365. Furthermore, the levels of these two miRNAs were reduced by ~30% in brown fat
Sun et al. Page 2
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
of ob/ob mice, animals in which brown fat activity was impaired (Fig. S1d) 17. Their levels
in BAT were not changed in animals that were exposed to cold temperature (Fig. S1e) or in
cell cultures that were treated with cAMP to induce the thermogenesis program (Fig. S1f).
To determine the functions of miR-193b and miR-365 in brown adipocytes, we transfected
brown fat SVF cells with locked nucleic acid (LNA) miRNA inhibitors and induced them to
differentiate for 4 days. Since miR-193a shares the same seed sequence with miR-193b, the
effects of a miR-193a inhibitor was also examined. For each inhibitor, RT-PCR detected a
greater than 90% decrease of corresponding miRNA levels (Fig. 2a), which reflects a
degradation or sequestration of miRNAs by inhibitors. Next, we performed mRNA
microarray analysis to test whether knockdown of miRNAs caused global up-regulation of
their targets. As predicted by TargetScanv5.118, 559 and 513 messages are predicted targets
of miR-193a/b and miR-365 (context score<?0.2) respectively; 469 and 404, respectively,
were expressed above background in our array data. The relative expression of each gene
was calculated as a ratio of expression in knockdown vs. control cells, and the cumulative
fraction was plotted as a function of the relative expression. The cumulative curve of the
miRNA target genes shifted significantly to the right relative to the curve of the control
genes that comprise genes without predicted miRNA target sites (Fig. 2b), indicating that
miRNA targets, as a group, tended to be upregulated upon miRNA inhibitor transfection.
Thus we conclude that these inhibitors functionally block downregulation of target miRNAs
in cells. Note that both miR-193a and miR-193b inhibitors caused upregulation of miR-193a/
b-targeted mRNAs, suggesting that either inhibitor was sufficient to suppress this miRNA
family.
Blocking miR-193a/b and/or miR-365 but not the control miRNA caused a remarkable
reduction in lipid accumulation in brown adipocytes differentiated from SVF cells and
brown preadipocytes (Sca-1+/CD45?/CD11b?) purified as described by Tseng laboratory 19
(Fig. 2c, Fig. S2a,b,c). A substantial fraction of transfected cells had a fibroblast-like
appearance (Fig. S2d). These effects of the inhibitors could be reversed by co-transfection
with miRNA mimics of miR-193a, miR-193b, and miR-365 (Fig. 2d), establishing the
specificity of miRNA knockdown. As assayed by real-time PCR, cells transfected with
miRNA inhibitors displayed marked down-regulation of adipogenesis markers common in
brown and white fat including AdipoQ, Cebpa, Fabp4 and Ppar? (Fig. 2e, Fig. S2c). A more
dramatic decrease was observed in expression of several brown fat enriched markers ?
Ucp1, Ppar?, Pgc-1?, Dio2, Prdm16 and Cidea (Fig. 2f, g, Fig. S2c). The reduction of Ucp1
expression was confirmed by Western blotting (Fig. 2g, Fig. S2e). However, the expression
of these genes was not altered in mature brown adipocytes transfected with miRNA
inhibitors (Fig. S2f), suggesting that these miRNAs perform their primary functions during
development and not in mature adipocytes. In addition, miR-193a/b and miR-365 were also
required for white fat adipogenesis (Fig. S2h, i), indicating that they were general regulators
of adipogenesis with an additional role in supporting the development of brown fat cells.
Among the conserved targets predicted by TargetScanv5.1, Runx1T1 is one of the top
candidates of miR-193b. Runx1t1 inhibits brown fat adipogenesis (Fig. S3a-e) and, as
reported previously, inhibits white adipogenesis in 3T3-L1 cells 20?22. Upon blocking
miR-193a/b, Runx1t1 was upregulated at both the messenger RNA (Fig. 2h) and the protein
levels (Fig. S3f). To prove that miR-193b can directly target Runx1t1 mRNA, we cloned the
3?UTR segment of Runx1t1 containing the predicted miR-193b target site (or a mutated seed
site) into the psiCHECK-2 vector. Each of the reporter constructs was co-transfected with
miR-193b mimic into 293T cells. Luciferase reporter assay showed that miR-193b mimic
reduced the activity of the reporter with a wild-type 3?UTR but not the one with mutations in
the seed sequences (3?UTR_Mut) (Fig 2. i). This demonstrates that miR-193b directly
Sun et al. Page 3
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
interacts with the predicted target sites in the Runx1t1 mRNA, and the downregulation of
Runx1t1 partially explains the role of miR-193b during adipogenesis.
Because previous studies have shown that brown fat and skeletal muscle share a common
developmental origin 13, 14, we suspected that blockage of the brown adipocyte lineage by
knockdown of miR-193b and/or miR-365 might switch the fate of brown preadipocytes to
the muscle lineage. Indeed, RT-PCR analysis showed that expression of several myogenic
markers (Ckm, Myf5, Myf6, Myod and Myog) was significantly induced (Fig. 3a), indicating
a tendency towards myogenesis in the inhibitor-transfected brown preadipocytes.
The induction of myogenesis in brown adipocytes could be a direct effect of blocking
miR-193b and/or miR-365, or secondary to the inhibition of brown adipogenesis as muscle
markers are downregulated during brown fat differentiation 23. To further distinguish among
these possibilities, we used retroviral vectors to express miR-193b and/or miR-365 in C2C12
myoblasts which were subsequently induced to differentiate. At day 6, C2C12 cells
expressing the control virus differentiated into elongated multinucleated myotube syncytia,
whereas cells expressing miR-193b and/or miR-365 failed to differentiate (Fig. 3b, Fig. S4a).
Similar results were observed when miR-193a was ectopically expressed (Fig. S4b, c, d).
Real-time PCR (Fig. 3d) and Western blot (Fig. 3c, Fig. S4e) analyses confirmed that
ectopic expression of either miRNA decreased the mRNA levels of the myogenic markers
Myf5, Myf6, Myog, Ckm, Tnni2, Tnnt3 and Casq1, as well as the level of myosin protein.
This analysis thus demonstrates that miR-193b-365 can directly repress myogenesis, thereby
contributing to the regulation of brown fat versus muscle lineage determination.
Among the conserved targets predicted by TargetScanv5.1 are Cdon (also named Cdo) and
Igfbp5, both previously implicated as pro-myogenic factors. Cdon is a cell surface receptor
that stimulates post-translational activation of myogenic bHLH factors and E proteins, and
increases muscle-specific transcription 24, 25, 26. Knocking down Igfbp5 also impairs
myogenic differentiation of C2C12 and primary skeletal muscle cells 27. Real-time PCR and
Western blot analysis showed that the levels of both Cdon and Igfbp5 mRNAs and protein
were significantly reduced in C2C12 cells expressing miR-193b (Fig. 3e,f, Fig. S4f). We
also examined their expression in cultured brown adipocytes transfected with LNA-193a/b
inhibitors, and found that their expression was upregulated (Fig. 3g). To further establish
that miR-193b directly down-regulates Cdon and Igfbp5 expression, we performed luciferase
reporter assay as we did for Runx1t1. As we expected, miR-193b mimic reduces the
activities of both Cdon and Igfbp5 reporters with a wild-type 3?UTR but not reporters with
mutations in the seed sequences in the 3?UTRs (3?UTR_Muts) (Fig 3h). This demonstrates
that miR-193b directly interacts with both predicted target sites.
Not only did ectopic expression of miR-193b repress myogenesis by C2C12 myoblasts, it
also upregulated the mRNAs encoding two master adipogenic factors Ppar? and Cebp? by
~10 fold and ~2.5 fold respectively (Fig. S5a). Furthermore, when exposed to pro-
adipogenic differentiation conditions (detailed in Methods), C2C12 cells expressing
miR-193b showed a round, lipid droplet-containing appearance, which resembled the
morphology of adipocytes (Fig. 4a). Ectopic expression of miR-193b repressed the
expression of myogenic markers Pax3 and MyoD (Fig. 4b, Fig. S5c) while it promoted a
significant upregulation of the common adipogenesis markers AdipoQ, Ppar?, Cebp? and
Fabp4 as well as brown fat selective markers, Ucp1, Cidea, Prdm16 and Ppar? (Fig. 4b, c).
Strikingly, the expression of markers such as AdipoQ, Cebp?, Ppar? and Fabp4 was
comparable to their levels in cultured brown adipocytes (Fig S5b). The miR-193b-induced
adipocytes also displayed an oxygen consumption rate (ORC) profile characteristic of brown
adipocytes. Although ORC for basal respiration, non-mitochondrial respiration, and
respiration capacity were not changed by miR-193b expression, a significantly higher ORC
Sun et al. Page 4
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
for proton leakage and a lower ORC for ATP turnover were observed in miR-193b-induced
adipocytes (Fig. 4e). Bona fide brown adipocytes should initiate a thermogenesis program in
response to beta-adrenergic stimulation, which can be mimicked by cAMP treatment. In
response to cAMP treatment, the thermogenic makers, Ucp1 and Pgc-1a, were upregulated
by ~15- and ~5-fold respectively in miR-193b-expressing C2C12 cells (Fig. 4d). Thus,
miR-193b can induce brown fat adipogenesis in C2C12 myoblast cells.
C2C12 myoblasts are known to be able to differentiate into adipocytes28. To exclude the
possibility that the adipogenesis of C2C12 cells is due to effects of their transformation, and
also to test whether the effects of miR-193b on myoblasts are conserved between mouse and
human, we retrovirally expressed miR-193b in primary human myoblasts which were
subsequently exposed to myogenic or adipogenic differentiation conditions (detailed in
Methods). MiR-193b, but not miR-365 (data not shown), significantly repressed myogenesis
(Fig S5d, e, f) and promoted the expression of all 5 adipogenic markers we examined
(Fabp4, AipoQ, Cebpa, Lpl, Pparg) (Fig S5g). Together, our studies establish that
miR-193b?s functions in repressing myogenesis and promoting adipogenesis are conserved
between mouse and human.
Prdm16 has been reported to be the ?master? regulator of BAT lineage
determination 13, 14, 29, 30. To determine whether induction of miR-193b-365 is part of the
Prdm16-induced program, we used retroviral vectors to introduce Prdm16 into subcutaneous
primary white preadipocytes and C2C12 myoblasts. By day 6 of differentiation, both
miR-193b and miR365 were significantly upregulated in cells ectopically expressing
Prdm16 (Fig. 5a, Fig. S6a, b). Conversely, retroviral shRNA knockdown of Prdm16 in
brown adipocyte cultures resulted in ~75% decrease in miR-193b expression and ~50%
decrease in miR-365 expression (Fig. 5b). Thus, miR-193b-365 is regulated by Prdm16.
Sequence analysis of the promoter region of miR-193b-365 by ExPlain 3.0 of BIOBASE
predicted three Ppar?/RXR binding sites within the 1 KB segment upstream of miR-193b
(Fig. 5e). Ppar? is a brown fat-selective transcriptional factor and is important for fatty acid
oxidation 31, 32 and suppressing expression of muscle-associated proteins in brown adipose
tissue 33. Interestingly, the expression of Ppar? could be induced by ectopic expression of
Prdm16 in primary white preadipocytes (Fig. S6a) and Ppar?-deficient mouse embryonic
fibroblasts 29. Ppar? can also directly interact with Prdm16 13. Thus, we hypothesized that
Prdm16 might regulate miR-193b-365 through Ppar?. To test this hypothesis, we knocked
down Prdm16 in primary brown adipocyte cultures, which resulted in about 80% decrease
of Ppar? mRNA (Fig. 5c). Consistently, the induction of Prdm16 and Ppar? was slightly
prior to the induction of miR-193b-365 during brown fat adipogenesis (Fig. 5d). A direct
interaction between Ppar? and the promoter region of miR-193b-365 was confirmed by
chromatin immunoprecipitation (ChIP) (Fig. 5e). In addition, a moderate but statistically
significant down-regulation of miR-193b and miR-365 was observed in primary brown
adipocyte cultures transfected with Ppar? siRNA (Fig. 5f) and in brown adipose tissues
from Ppar? knockout compared to wild- type mice (Fig. 5g). To rigorously prove that
Prdm16-Ppara regulates miR-193b-365 at the transcriptional level, we used Real-time PCR
to examine the levels of pri-miR-193b-365 and found that the pri-miRNA was regulated
similarly as mature miR-193b and miR-365 by Prdm16 and Ppara (Fig. S6c-h). Together,
these data suggest that Prdm16 can induce miR-193b-365 expression at least partially by
inducing expression of Ppar?.
Since ectopic expression of miR-193b promotes the expression of Prdm16 (Fig. 4c) and
since blocking miR-193b in brown preadipocytes results in a down-regulation of Prdm16
(Fig. 2f), we hypothesize a feed-forward loop that ensures differentiation of brown
adipocytes from bipotential brown adipocyte/myocyte progenitors (Fig S6m). To test
Sun et al. Page 5
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
whether the effects of miR-193b on brown fat adipogenesis can be solely attributed to its
effects on Prdm16, we blocked miR-193b-365 in brown adipocyte cultures ectopically
expressing Prdm16. Overexpression of Prdm16 in brown preadipocytes was not sufficient to
fully rescue the deficiency in adipogenesis due to a blockage of miR-193a/b or miR-365
(Fig. S6i-l). Thus, miR-193b likely regulates more factors additional to Prdm16 to control
brown fat adipogenesis.
To the best of our knowledge, the present work is the first study to investigate the functions
of miRNA in brown fat specification, and our results have revealed another layer of
regulation of brown fat lineage determination. Further functional characterization of
miR-193b and miR-365 in animal models and better understanding of the mechanisms
regulating brown fat development may lead to identification of novel therapeutic targets and
strategies against obesity and related metabolic disorders.
METHODS
Cell cultures
Primary brown adipocytes and SVF cells were fractionated and cultured according to
published methods with few modifications 34, 35. Briefly, 2 week old C57BL/6 mice were
sacrificed. Interscapular BAT were harvested and digested with collagenase (0.2%). SVF
cells were collected by centrifugation, red blood cells were lysated with NH4Cl and then
SVF were filtered through 40uM. Primary white SVF cells and adipocytes from
subcutaneous fat were isolated and fractionated according to published methods 36. Primary
SVF cells were cultured to confluence in DMEM with 10% New Born Calf Serum
(Invitrogen) and induced to differentiate for 2 days with DMEM containing 10%FBS
DMEM, Insulin 850nM (Sigma), Dexamethasone 0.5uM (Sigma), IBMX 250uM (Sigma),
Rosiglitazone 1uM (Cayman Chemical), T3 1nM (Sigma), and Indomethacin 125nM
(Sigma). The induction medium was replaced with DMEM containing 10% FBS and 160nM
insulin for 2 day. Then cells were incubated in DMEM with 10% FBS.
The immortalized brown adipocyte cell line used for ChIP was a generous gift from the Dr.
Ronald Kahn lab. Cells were cultured to confluence then exposed to differentiation media:
10%FBS DMEM, Insulin 20nM (Sigma), Dexamethasone 0.5uM (Sigma), IBMX 250uM
(Sigma), T3 1nM (Sigma), and Indomethacin 125nM (Sigma) for 2 days. Cells were then
switched to media containing 10%FBS, T3 (1nM) and Insulin (20nM).
C2C12 and HEK 293Tcells from the American Type Culture Collection (ATCC) were
cultured or differentiated according to manufacturer?s instructions.
Primary human myoblasts were purchased from ZenBio. Cells were cultured and
differentiated according to manufacturer?s instructions.
Animal studies
Male C57BL/6J mice, Ppar? knockout mice (B6:129S4) and ob/ob mice (000632) from the
Jackson Laboratory were maintained at the animal facility of the Whitehead Institute for
Biomedical Research. All animal experiments were performed with the approval of the
Massachusetts Institute of Technology Committee on Animal Care. Epididymal WAT,
interscapular BAT and skeletal muscle from 12 week old mice were harvested after
perfusion for miRNA expression profiling and RT-PCR. Tissues from 4?5 mice were pooled
for each RNA sample preparation. Brown fat of Ppar? knockout mice was harvested from 8
weeks old mice (male), and age-matched wild-type mice were used as a control. 8 week old
male C57BL/6 mice were kept in 4oC for 24 hours to stimulate brown fat thermogenesis.
Sun et al. Page 6
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
Plasmids and Viral Vectors
Authentic miRNA stem-loop and ~ 220 nucleotide flanking sequences on the 5? and 3? side
of the mmu-miR-193a/b and mmu-miR-365-1 gene were amplified from normal mouse
genomic DNA (Clontech) and cloned into a retroviral vector containing IRES-GFP as
described previously 37 for retrovirus production. The Prdm16 retroviral construct (15504),
Prdm16-shRNA retroviral construct (15505), and Pparg2 retroviral construct (8859) were
purchased from Addgene. Runx1t1 and its GFP vector control constructs are generous gift
from Rochford?s lab. Retroviral package vectors pcl-ECO and pcl-10A1 are from
IMGENEX.
To generate reporter constructs for luciferase assays, about 400 bp segments containing
predicted miRNA target sites in the 3?UTRs of Runx1t1, Cdon and Igfbp5 were cloned into
the psiCHECK-2 vector (Promega) between the XhoI and NotI sites immediately
downstream of the Renilla luciferase gene. To generate reporters with mutant 3?UTRs, five
nucleotides (CCAGT) in the target site complementary to the position 2?6 of miR-193b seed
region were mutated to GATCC by a QuikChange Site-Directed Mutagenesis kit according
to the manufacturer?s protocol (Stratagene).
Induction of brown fat adipogenesis in myoblasts
To induce miR-193b-expressing myoblasts for adipogenesis, C2C12 myoblasts or primary
human myoblasts were infected as described below, cultured to confluence, and then
exposed to brown adipocyte differentiation conditions: 10%FBS DMEM, Insulin 850nM
(Sigma), Dexamethasone 0.5uM (Sigma), IBMX 250uM (Sigma), Rosiglitazone 1uM
(Cayman Chemical), T3 1nM (Sigma), and Indomethacin 125nM (Sigma). After 2 days,
cells were incubated in culture medium containing insulin 160nM and Rosiglitazone 1uM
for another 2 days, and then were switched to 10% FBS DMEM. To stimulate
thermogenesis, cells were incubated with dibutyryl cAMP 0.5mM (Sigma) for 4 h.
FACS sorting
Brown fat SVF cells were isolated as described above. SVF cells were stained with a FITC-
conjugated CD45 antibody (Ebioscience), APC-conjugated CD11b (Ebioscience) antibody
and PE-conjugated Sca1 antibody (Ebioscience) for 15 mins on ice. Cells were washed
twice and then resuspended in PBS (2% FBS, PI). FACS sorting was performed at
Whitehead Institute core facility to enriched CD45? CD11b?Sca1+ preadipocytes.
Retrovirus production and Infection
Empty vector or expression plasmid (8 ?g) was co-transfected with retrovirus packaging
vector pCL-Eco (4 ?g) into 80% confluent 293T cells (100mm plate) using FuGene 6
according to the manufacturer?s protocol (Roche). Virus supernatant was collected 2 days
after transfection.
Primary white and brown fat SVF cells and C2C12 myoblasts were cultured to 30?50%
confluence and infected with retrovirus in the presence of 4 ?g/ml polybrene (Sigma).
Infection efficiency was generally higher than 80%, as judged by GFP expression when
viewed under the microscope or by FACS analysis.
Luciferase Reporter assay
293T cells were seeded in 96-well white assay plates (Corning) at a density of 30,000 cells
per well one day before transfection. Ten nanograms of each reporter construct were co-
transfected with miR-193b mimic or a mimic control (Dharmacon) at final concentration
50nM into 293T cells using Lipofectamine 2000 according to the manufacturer?s protocol
Sun et al. Page 7
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
(Invitrogen). After 48 hours, firefly and Renilla luciferase activities were measured with the
Dual-Glo luciferase assay system according to the manufacturer?s instructions (Promega).
Transfection of LNA miRNA inhibitor and siRNAs
When cultured SVF cells or sorted preadipocytes were grown to 70?80% confluence,
Locked Nucleic Acids (LNAs) miRNA inhibitors (100nM) or anti-Ppar? siRNA (200nM)
were transfected by DharmaFect 2 (6ul/ml) according to the manufacturer?s instruction. 24
hrs after transfection, cells were recovered in full culture media and grown to confluence for
differentiation. LNAs inhibitors were from Exiqon, LNA-193b (139676-00), LNA-365
(139215-00), LNA-193 (139481-00) and LNA-Ctl (199002-08). siRNAs for Ppar? were
from Invitrogen, MSS207857 and negative control (12935300)
miRNA microarray and data analysis
miRNA microarray and analysis were performed as previously described 38. Specifically,
microarrays with miRNA content corresponding to miRBase v10.1 (six probes for each
miRNA on one chip) were used. After global normalization, miRNAs with an intensity more
than 500 arbitrary units were considered as expressed. Differentially regulated miRNAs
were identified by one-way ANOVA analysis (P <0.1). 91 miRNAs expressed in at least one
sample and differentially expressed between three tissues were selected for clustering
analysis. Unsupervised hierarchical clustering was performed with average linkage and
uncentered correlation as the similarity metric using Cluster3.0 39. The heat map was
generated in Java Treeview. Accession number: E-MEXP-2553 (ArrayExpress).
mRNA microarray and data analysis
Total mRNA was obtained from primary brown adipocytes transfected with miRNA
inhibitor or Control inhibitor. Affymetrix arrays were performed by the Genome
Technology Core at Whitehead Institute. Microarray data were preprocessed with RMA
from the Affymetrix package in Bioconductor using custom probeset definitions for NCBI
Entrez Genes derived from previous method40. To reduce data noise, genes with intensities
below threshold (log2(Value)<3, arbitrary units) were removed from further analysis.
TargetScan v5.1 18 was used for predicting miRNA targets. Relative expression of each
gene was calculated as the log2 ratio between the intensity of the mRNA in the miRNA
inhibitor sample relative to the intensity of the control inhibitor sample. The cumulative
fraction was plotted as a function of the relative expression. The cumulative curves for both
miRNA targets and the genes without miRNA binding sites were plotted, and one-sided
Kolmogorov-Smirnov test was performed as the statistical test. mRNA microarray data have
been uploaded to GEO GSE27614.
Quantitative real-time PCR assay and Western blot
RT PCR for miRNA and mRNA was performed and analyzed as previously described 38.
Primer sequences are listed in Supplementary Table SI. 18S was used as an internal control.
For Western blot analyses, cells or tissues were lysed in RIPA buffer (0.5% NP-40, 0.1%
SDS, 150 m M NaCl, 50 mM Tris-Cl (pH 7.5)). Proteins were separated by SDS?PAGE,
transferred to Nitrocellulose membrane (Millipore) and probed with anti-Cdon (AF2429,
R&D system), anti-Igfbp5 (AF578, R&D system), Anti-Ucp1 (ab10983, Abcam), anti-
MyoD (SC-760, Santa Cruz), anti-PAX3 (ab15717, Abcam), anti-Runx1t1 (SC-9737, Santa
Cruz),and anti-Myosin (MF20, Developmental Studies Hybridoma Bank) antibodies.
Sun et al. Page 8
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
Chromatin immunoprecipitation
Immortalized brown fat cell culture cells (3?10^7 cells per sample) were fixed with
formaldehyde at 1% final concentration for 20 minutes. The cross-linking was quenched
with ice-cold 2.5M glycine, and the cells were rinsed twice with 1x PBS. Cross-linked cells
were resuspended, then lysed with detergent to separate the nuclear pellet which was
resuspended in 3ml sonication buffer (50mM Tris HCl, 140mM NaCl, 1mM EDTA, 1%
Triton-X 100, 0.1% Na-deoxycholate, 0.1% SDS), and then sonicated to shear the cross-
linked DNA to an optimal fragment size ranging from 200 to 500 bp. Sonication was
performed using a Branson sonifier (at Power 4.5 for 24W at maximum power) for nine 20-
second pulses (with a 60-second pause between pulses). Simultaneously, magnetic protein-G
beads (Dynal) were incubated with 20ug polyclonal antibody against Ppar? (SC-9000X,
Santa Cruz) or 20ug IgG control (rat IgG #012-000-003 from Jackson) for 6 hours on ice.
An aliquot (1/600) of the sonicated nuclear pellet was set aside as the whole cell extract
control (WCE) and then taken through the rest of the protocol exactly as the
immunoprecipitated (IP) fraction. The remainder (about 3ml) of the sonication sample was
combined with the preincubated beads and this immunoprecipitation was run overnight at 4
degrees C. The beads were then collected with a magnet and washed with RIPA buffer 6
times. Bound DNA-protein complexes were eluted from the beads by reversal of cross-
linking through heating to 65 degrees C overnight. The enriched IP and unenriched WCE
DNA fragments were purified using RNAse A and proteinase K incubation, phenol-
chloroform extraction, and then ethanol precipitation. The resulting DNA was then used for
gene-specific PCR.
Measurements of oxygen consumption and extracellular acidification rates
C2C12 cells were seeded (5,000 cells/well) into gelatin-coated XF24 V7 cell culture
microplates (Seahorse Bioscience) and cultured overnight at 37?C with 5% CO2. The next
day, cells were transduced with retroviruses expressing miR-193b or empty vector in the
presence of polybrene, cultured to confluence, and induced to differentiate with a brown
adipocyte cocktail. As a control, primary brown preadipocytes were isolated, seeded into
gelatin-coated XF24V7 cell culture microplates, and differentiated into mature brown
adipocytes. At day 6 of differentiation, the media was replaced with prewarmed XF24 assay
media for 1 h; this unbuffered media consisted of DMEM (Sigma), 1 mM Glutamax-1
(Invitrogen), 2 mM pyruvate, 141 mM NaCl, and 25 mM glucose. Using the Seahorse
Bioscience XF24-3 Extracellular Flux Analyzer, theO2 tension immediately around the cells
was measured by optical fluorescent biosensors embedded in a sterile disposable cartridge
placed into the wells of the microplate during the assay. O2 consumption rate (OCR) was
calculated by plotting the O2 tension of the media in the microenvironment above the cells
as a function of time (pmoles/min). OCR was measured during 4 min cycles repeated four
times at 10-min intervals. Firstly, basal respiration was assessed in untreated cells. Secondly,
ATP turnover was calculated in response to oligomycin (Calbiochem) treatment (10 ?M).
Maximum respiratory capacity was assessed after FCCP (Sigma) stimulation (1 ?M).
Finally, mitochondrial respiration was blocked by Rotenone (Sigma) (1 ?M) and the residual
OCR was considered non-mitochondrial respiration. Proton leak was calculated by
subtracting the ATP turnover and the non-mitochondrial respiration components of basal
respiration.
Statistical analysis
Data are expressed as means ? SE unless otherwise indicated. Student?s t test (unpaired,
two-tailed) was used to compare the two groups, and the P value was calculated in Excel
(Microsoft) or GraphPad Prism 5 (GraphPad Software). P < 0.05 was considered as
statistically significant.
Sun et al. Page 9
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
Supplementary Material
Refer to Web version on PubMed Central for supplementary material.
Acknowledgments
This work is supported by NIH grants DK047618, DK 068348, DK076848, and 5P01 HL066105, grant
C-382-641-001-091 from the Singapore-MIT Alliance (SMA) and a graduate fellowship from SMA. Thanks for
intellectual support, materials, and advice from members of the laboratories of Drs. Patrick Seale, David Bartel,
Charles Emerson, and from all members of the Lodish laboratory. Thanks for Rochford?s lab for their generous
gifts of Runx1t1 plasmid.
References
1. Seale P, Kajimura S, Spiegelman BM. Transcriptional control of brown adipocyte development and
physiological function--of mice and men. Genes Dev. 2009; 23:788?797. [PubMed: 19339685]
2. Gesta S, Tseng YH, Kahn CR. Developmental origin of fat: tracking obesity to its source. Cell.
2007; 131:242?256. [PubMed: 17956727]
3. Cypess AM, et al. Identification and importance of brown adipose tissue in adult humans. N Engl J
Med. 2009; 360:1509?1517. [PubMed: 19357406]
4. van Marken Lichtenbelt WD, et al. Cold-activated brown adipose tissue in healthy men. N Engl J
Med. 2009; 360:1500?1508. [PubMed: 19357405]
5. Virtanen KA, et al. Functional brown adipose tissue in healthy adults. N Engl J Med. 2009;
360:1518?1525. [PubMed: 19357407]
6. Connolly E, Morrisey RD, Carnie JA. The effect of interscapular brown adipose tissue removal on
body-weight and cold response in the mouse. Br J Nutr. 1982; 47:653?658. [PubMed: 6282304]
7. Lowell BB, et al. Development of obesity in transgenic mice after genetic ablation of brown adipose
tissue. Nature. 1993; 366:740?742. [PubMed: 8264795]
8. Hamann A, Flier JS, Lowell BB. Decreased brown fat markedly enhances susceptibility to diet-
induced obesity, diabetes, and hyperlipidemia. Endocrinology. 1996; 137:21?29. [PubMed:
8536614]
9. Feldmann HM, Golozoubova V, Cannon B, Nedergaard J. Ucp1 ablation induces obesity and
abolishes diet-induced thermogenesis in mice exempt from thermal stress by living at
thermoneutrality. Cell Metab. 2009; 9:203?209. [PubMed: 19187776]
10. Kopecky J, Clarke G, Enerback S, Spiegelman B, Kozak LP. Expression of the mitochondrial
uncoupling protein gene from the aP2 gene promoter prevents genetic obesity. J Clin Invest. 1995;
96:2914?2923. [PubMed: 8675663]
11. Kopecky J, et al. Reduction of dietary obesity in aP2-Ucp transgenic mice: mechanism and adipose
tissue morphology. Am J Physiol. 1996; 270:E776?786. [PubMed: 8967465]
12. Bartelt A, et al. Brown adipose tissue activity controls triglyceride clearance. Nat Med. 17:200?
205. [PubMed: 21258337]
13. Seale P, et al. Prdm16 controls a brown fat/skeletal muscle switch. Nature. 2008; 454:961?967.
[PubMed: 18719582]
14. Kajimura S, et al. Initiation of myoblast to brown fat switch by a Prdm16-C/EBP-beta
transcriptional complex. Nature. 2009; 460:1154?1158. [PubMed: 19641492]
15. Kawaji H, et al. CAGE Basic/Analysis Databases: the CAGE resource for comprehensive promoter
analysis. Nucleic Acids Res. 2006; 34:D632?636. [PubMed: 16381948]
16. Carninci P, et al. The transcriptional landscape of the mammalian genome. Science. 2005;
309:1559?1563. [PubMed: 16141072]
17. Hogan S, Himms-Hagen J. Abnormal brown adipose tissue in obese (ob/ob) mice: response to
acclimation to cold. Am J Physiol. 1980; 239:E301?E309. [PubMed: 7425122]
18. Friedman RC, Farh KK, Burge CB, Bartel DP. Most mammalian mRNAs are conserved targets of
microRNAs. Genome Res. 2009; 19:92?105. [PubMed: 18955434]
Sun et al. Page 10
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
19. Schulz TJ, et al. Identification of inducible brown adipocyte progenitors residing in skeletal muscle
and white fat. Proc Natl Acad Sci U S A. 2010; 108:143?148. [PubMed: 21173238]
20. Payne VA, et al. C/EBP transcription factors regulate SREBP1c gene expression during
adipogenesis. Biochem J. 2009; 425:215?223. [PubMed: 19811452]
21. Blumberg JM, et al. Complex role of the vitamin D receptor and its ligand in adipogenesis in 3T3-
L1 cells. J Biol Chem. 2006; 281:11205?11213. [PubMed: 16467308]
22. Rochford JJ, et al. ETO/MTG8 is an inhibitor of C/EBPbeta activity and a regulator of early
adipogenesis. Mol Cell Biol. 2004; 24:9863?9872. [PubMed: 15509789]
23. Timmons JA, et al. Myogenic gene expression signature establishes that brown and white
adipocytes originate from distinct cell lineages. Proc Natl Acad Sci U S A. 2007; 104:4401?4406.
[PubMed: 17360536]
24. Cole F, Zhang W, Geyra A, Kang JS, Krauss RS. Positive regulation of myogenic bHLH factors
and skeletal muscle development by the cell surface receptor CDO. Dev Cell. 2004; 7:843?854.
[PubMed: 15572127]
25. Kang JS, Mulieri PJ, Miller C, Sassoon DA, Krauss RS. CDO, a robo-related cell surface protein
that mediates myogenic differentiation. J Cell Biol. 1998; 143:403?413. [PubMed: 9786951]
26. Kang JS, et al. A Cdo-Bnip-2-Cdc42 signaling pathway regulates p38alpha/beta MAPK activity
and myogenic differentiation. J Cell Biol. 2008; 182:497?507. [PubMed: 18678706]
27. Ren H, Yin P, Duan C. IGFBP-5 regulates muscle cell differentiation by binding to IGF-II and
switching on the IGF-II auto-regulation loop. J Cell Biol. 2008; 182:979?991. [PubMed:
18762576]
28. Teboul L, et al. Thiazolidinediones and fatty acids convert myogenic cells into adipose-like cells. J
Biol Chem. 1995; 270:28183?28187. [PubMed: 7499310]
29. Seale P, et al. Transcriptional control of brown fat determination by Prdm16. Cell Metab. 2007;
6:38?54. [PubMed: 17618855]
30. Kajimura S, et al. Regulation of the brown and white fat gene programs through a Prdm16/CtBP
transcriptional complex. Genes Dev. 2008; 22:1397?1409. [PubMed: 18483224]
31. Barbera MJ, et al. Peroxisome proliferator-activated receptor alpha activates transcription of the
brown fat uncoupling protein-1 gene. A link between regulation of the thermogenic and lipid
oxidation pathways in the brown fat cell. J Biol Chem. 2001; 276:1486?1493. [PubMed:
11050084]
32. Braissant O, Foufelle F, Scotto C, Dauca M, Wahli W. Differential expression of peroxisome
proliferator-activated receptors (PPARs): tissue distribution of PPAR-alpha, -beta, and -gamma in
the adult rat. Endocrinology. 1996; 137:354?366. [PubMed: 8536636]
33. Tong Y, et al. Suppression of expression of muscle-associated proteins by PPARalpha in brown
adipose tissue. Biochem Biophys Res Commun. 2005; 336:76?83. [PubMed: 16125138]
34. Cannon B, Nedergaard J. Cultures of adipose precursor cells from brown adipose tissue and of
clonal brown-adipocyte-like cell lines. Methods Mol Biol. 2001; 155:213?224. [PubMed:
11293074]
35. Tseng YH, Ueki K, Kriauciunas KM, Kahn CR. Differential roles of insulin receptor substrates in
the anti-apoptotic function of insulin-like growth factor-1 and insulin. J Biol Chem. 2002;
277:31601?31611. [PubMed: 12082100]
36. Rodbell M. Metabolism of Isolated Fat Cells. I. Effects of Hormones on Glucose Metabolism and
Lipolysis. J Biol Chem. 1964; 239:375?380. [PubMed: 14169133]
37. Zhang J, Socolovsky M, Gross AW, Lodish HF. Role of Ras signaling in erythroid differentiation
of mouse fetal liver cells: functional analysis by a flow cytometry-based novel culture system.
Blood. 2003; 102:3938?3946. [PubMed: 12907435]
38. Xie H, Lim B, Lodish HF. MicroRNAs induced during adipogenesis that accelerate fat cell
development are downregulated in obesity. Diabetes. 2009; 58:1050?1057. [PubMed: 19188425]
39. de Hoon MJ, Imoto S, Nolan J, Miyano S. Open source clustering software. Bioinformatics. 2004;
20:1453?1454. [PubMed: 14871861]
40. Dai M, et al. Evolving gene/transcript definitions significantly alter the interpretation of GeneChip
data. Nucleic Acids Res. 2005; 33:e175. [PubMed: 16284200]
Sun et al. Page 11
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
Figure 1. miR-193b-365 is enriched in BAT
(a), Heat map showing the expression of miRNAs that are enriched in BAT compared to
epididymal WAT and skeletal muscle. Red denotes higher and green denotes lower relative
to the mean of the six samples for each miRNA. (P < 0.1, ANOVA). (b), Real-time PCR
analysis of miR-193b, miR-365, and a control miRNA, miR-223 expression levels in BAT
relative to other adult mouse tissues. n=3. (c), Real-time PCR analysis of miR-193b and
miR-365 expression levels during adipogenesis of primary brown adipocyte cultures. n=3.
Means ? SEM.
Sun et al. Page 12
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
Figure 2. miR-193b-365 is required for brown adipocyte adipogenesis
(a), SVF cells from brown fat were transfected with LNA miRNA inhibitors (100nM) one
day before differentiation. RNAs were harvested at day 4. Real-time PCR was used to
examine the expression of these miRNAs. n=3. (b), mRNAs from cultured primary brown
adipocytes (Day 4) transfected with each inhibitor or Control inhibitor were analyzed by
microarray analysis. On the x-axis is the relative expression of each gene calculated as a
log2 ratio (x-axis) between its intensity in the miRNA-inhibited sample and its intensity in
the control inhibitor sample. The cumulative fraction (y-axis) was plotted as a function of
the relative expression (x-axis). ?miRNA targets? (red line) represents the population of
genes containing miRNA binding sites predicted by TargetScan, and ?Control? (black line)
represented all other genes lacking binding sites for the miRNA. The ?targets? curve shifts
to the right with a P value <0.05 as determined by the one-sided Kolmogorov-Smirnov test,
indicating a trend of up-regulation of predicted targets in response to transfection of the
miRNA inhibitor. (c), Oil red O staining was used to determine the accumulation of lipid
droplets in brown adipocytes (Day 4). (d), SVF cells from brown fat were co-transfected
with LNA miRNA inhibitors (100nM) and miRNA mimics (mimic-miR-193a 16.7nM,
mimic-miR-193b 16.7nM and mimic-miR-365 16.7nM, or Control mimic 50nM) one day
before differentiation. Four days after differentiation, ORO staining was used to determine
lipid droplet content. (e), Real-time PCR analysis of the expression of adipogenesis markers
and (f), Brown fat markers. n=3. (g), Western blot to examine the expression of Ucp1. (h),
Effect of miR-193 knockdown on expression of Runx1t1. Real-time PCR was performed to
examine the expression of Runx1t1. Runx1t1-P1 and Runx1t1-P2 represent two sets of PCR
primers. n=3. (i), Luciferase reporter assay to examine the interactions between miR-193b
and the predicted target site in Runx1t1 3?UTR. Plasmids with the Runx1t1 3?UTRs or
mutated UTRs were co-transfected with miR-193b mimic or a control mimic into 293T cells.
Renilla luciferase activity was measured by Dual-Glo luciferase assay system and
Sun et al. Page 13
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
normalized to internal control firefly luciferase activity. n=6. * P < 0.05, Student?s t-test;
Means ? SEM.
Sun et al. Page 14
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
Figure 3. Ectopic expression of miR-193b and/or miR-365 inhibits C2C12 myogenic
differentiation
(a), SVF cells from brown fat were transfected with LNA miRNA inhibitors (100nM) one
day before differentiation. At day 4, RNAs were extracted and Real-time PCR was
performed to detect the expression of myogenic markers. n=3. (b), Representative
micrographs of cells (Day 6 in 2% horse serum) differentiated from C2C12 myoblasts
expressing retroviral miR-193b and/or miR-365, or control. GFP was expressed under
control of an IRES downstream of the miRNA to visualize transfected cells. (c), Western
blot with triplicate biological repeats to examine the expression of myosin upon ectopic
expression of miR-193b and/or miR-365. (d), Real-time PCR analysis for expression of
muscle markers. n=3. (e), Real-time PCR and (f), Western analysis for predicted miR-193b
targets, cell adhesion molecule-related/down-regulated by oncogenes (Cdon) and insulin-
like growth factor binding protein 5 (Igfbp5), in C2C12 cells expressing miR-193b or a
control vector. n=3. (g), SVF cells from brown fat were transfected with LNA-miR-193a
and/or LNA-miR-193b, and differentiated for 4 days. Real-time PCR was performed to
examine the expression of Cdon and Igfbp5. n=6. (h), Luciferase reporter assay to examine
the interactions between miR-193b and the predicted target site in Cdon and Igfbp5 3?UTR.
Plasmids with the Igfbp5 or Cdon 3?UTRs or mutated UTRs were co-transfected with
miR-193b mimic or a control mimic into 293T cells. Renilla luciferase activity was
measured by Dual-Glo luciferase assay system, normalized to internal control firefly
luciferase activity. n=6. * P < 0.05, Student?s t-test; Means ? SEM.
Sun et al. Page 15
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
Figure 4. Ectopic expression of miR-193b induces C2C12 to form brown adipocytes under
adipogenic differentiation conditions
(a), C2C12 cells ectopically expressing miR-193b or control were exposed to pro-adipogenic
conditions (described in Methods) for 5 days. ORO staining was used to assess lipid
accumulation in cells. Representative micrographs of these cells are depicted (bottom row).
(b). Western blot for myogenic markers Pax3, MyoD and brown fat marker Ucp1. n=3. (c),
Real-time PCR analysis for expression of common adipogenesis markers (upper row) and
brown fat selective markers (bottom row). n=3. (d), C2C12 cells expressing miR-193b (day
6) were stimulated with 500uM dibutyrul cAMP for 4h, and the expression of thermogenic
markers, Pgc-1? and Ucp1 was examined by real-time PCR. n=3. (e), The metabolic profile
of C2C12 cells expressing miR-193b (day 6) was assessed using the Seahorse XF24
Extracellular Flux Analyzer. A representative curve of the oxygen consumption rates (OCR)
of control and miR-193b expressing cells at their basal states and upon treatment with drugs
used to dissect the multiple components of the respiration process is plotted in the top-left
panel. The parameters analyzed are represented by different colors in the upper panel and
quantitated in other panels. In vitro differentiated primary brown adipocytes (BAT) were
used as a reference. n=8. * P < 0.05, Student?s t-test; Means ? SEM.
Sun et al. Page 16
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
Figure 5. miR-193b-365 is regulated by Prdm16
(a), Subcutaneous white pre-adipocytes (left) and C2C12 myoblasts (right) were infected by
retrovirus expressing Prdm16 two days before differentiation. 5 days after differentiation,
real-time PCR were performed to examine the expression of miR-193b, miR-365, and as a
control miR-223. n=3. (b), Primary brown preadipocytes were infected by retrovirus
expressing shRNA targeting Prdm16 two days before differentiation. By D5 of
differentiation, real-time PCR was used to examine the mRNA level of Prdm16 (left), and
miR-193b, miR-365, and the control miR-223 (right). n=3. (c), Real-time PCR analysis for
Ppar? in primary brown adipocytes retrovirally expressing shRNA for Prdm16. (d), Real-
time PCR analysis of miR-193b, miR-365, Prdm16 and Ppara expression levels during
adipogenesis of primary brown adipocyte cultures. n=3. (e), ChIP analysis for the interaction
between Ppara and the promoter region of miR-193b-365. Immortalized brown adipocyte
cultures (Day 5) were fixed and sheared by ultrasonication. Immunoprecipitation was
performed with anti-Ppar? and control IgG. Recovered DNA was amplified by 3 pairs (P1,
P2 and P3) of primers designed to span the 1Kb promoter region. Input samples are in the
top panel and immunoprecipitated ones in the bottom. (f), Primary brown preadipocytes
were transfected with siRNA targeting Ppar?, and differentiated for 3 days. RT- PCR was
performed to examine the expression of Ppar?, and miR-193b and miR-365. Ppar?and
miR-223 were used as controls. n=3. (g), RT-PCR was performed to examine the expression
of miRNAs in brown adipose tissue isolated from Ppar? knockout mice (8 week old, Male).
Sun et al. Page 17
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript
Age-matched wild- type mice were used as control. n=6. * P < 0.05, Student?s t-test; Means
? SEM.
Sun et al. Page 18
Nat Cell Biol. Author manuscript; available in PMC 2012 February 1.
NIH-PA Author Manuscript
NIH-PA Author Manuscript
NIH-PA Author Manuscript