The intracellular fatty acid-binding proteins (FABPs) are a well-conserved family that function as lipid chaperones. Ongoing studies are focused on identification of the mechanistic complexity and vast biological diversity of different isoforms of FABPs. However, the molecular mechanism of FABP5 in the regulation of milk fat synthesis in the mammary gland of dairy cows is still largely unknown. Here, we report that FABP5 acts as a critical regulator of terol response element-binding protein-1c (SREBP-1c) gene expression induced by methionine (Met) and estrogen (E2) in bovine mammary epithelial cells (BMECs). We observed that the expression of FABP5 was markedly higher in dairy cow mammary tissue during the lactating period than the puberty period and the dry period. FABP5 is located in the cytoplasm, and Met and E2 significantly increase the protein levels of FABP5 in BMECs. Using gene function study approaches, we revealed that FABP5 positively regulates SREBP-1c gene expression and promotes milk fat synthesis. We confirmed that FABP5 is required for Met- and E2-induced SREBP-1c gene expression and milk fat synthesis. We further uncovered that fatty acids are needed for FABP5-mediated SREBP-1c gene expression. Thus, our study demonstrates that FABP5 is a critical regulator of Met- and E2-induced SREBP-1c gene expression leading to milk fat synthesis.
Amino acids can stimulate milk fat
synthesis, but the underlying
molecular mechanism is still largely unknown. In this study, we studied
the regulatory role and corresponding molecular mechanism of cAMP
response element-binding protein-regulated transcription coactivator
2 (CRTC2) in amino acid-induced milk fat synthesis in mammary epithelial
cells. We showed that leucine and methionine stimulated CRTC2 but
not p-CRTC2(Ser171) expression and nuclear localization in cow mammary
epithelial cells. Knockdown of CRTC2 decreased milk fat synthesis
and sterol regulatory element binding protein 1c (SREBP-1c) expression
and activation, whereas its overexpression had the opposite effects.
Neither knockdown nor overexpression of CRTC2 affected β-casein
synthesis and phosphorylation of the machanistic target of rapamycin
(mTOR), suggesting that CRTC2 only regulates milk fat synthesis. CRTC2
knockdown abolished the stimulation of leucine and methionine on SREBP-1c
expression and activation. Knockdown or overexpression of CRTC2 did
not affect the protein level of cAMP-response element-binding protein
(CREB) and its phosphorylation but decreased or increased the binding
of p-CREB to the promoter of SREBP-1c gene and its
mRNA expression, respectively. Mutation of Ser171 of CRTC2 did not
alter the stimulation of CRTC2 on SREBP-1c expression and activation,
further suggesting that CRTC2 functions in the nucleus. mTOR inhibition
by rapamycin totally blocked the stimulation of leucine and methionine
on CRTC2 expression. The expression of CRTC2 was dramatically higher
in the mouse mammary gland of lactation period, compared with that
of the dry and puberty periods, whereas p-CRTC2(Ser171) was not changed,
further supporting that CRTC2 is a key transcription coactivator for
milk fat synthesis. These results uncover that CRTC2 is a key transcription
coactivator of amino acid-stimulated mTOR-mediated milk fat synthesis
in mammary epithelial cells.
Chemically induced proximity (CIP) is a powerful tool to study cellular functions. However with current CIP inducers it is difficult to directly modulate unligandable and endogenous targets, and therapeutic translational potential is also restricted. Herein, we combine CIP and chemical nanobody engineering and create cell-permeable small molecule-nanobody conjugate inducers of proximity (SNACIPs). The SNACIP inducer cRGT carrying a cyclic cell-penetrating peptide rapidly enters live cells and dimerizes eDHFR and GFP-variants. cRGT enables minute-scale, reversible, no-wash and dose-dependent control of cellular processes including signaling cascade, cargo transport and ferroptosis. Small-molecule motifs can also be installed via post-translational modifications. Therefore, latent-type SNACIPs including cRTC are designed that are functionally assembled inside living cells. cRTC contains a nanobody against an intrinsically disordered protein TPX2, a microtubule nucleation factor overexpressed in various cancers. Cancer cell proliferation is inhibited and tumor growth is suppressed in vivo. Hence, SNACIPs are valuable proximity inducers for regulating cellular functions.
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