HDI-STARR-seq library profiling of differential accessible chromatin regions (DARs) in livers of male, female and male treated with continuous growth hormone (cGH) mice.

Massively parallel reporter assays (MPRA) are widely used to discover functional enhancers but have largely been limited to transfected cell models, which are confounded by vector-induced innate immune responses and lack the physiologically relevant cellular and endogenous hormonal context and chromatin environment of complex mammalian tissues. Here, we combine hydrodynamic injection (HDI) with a modified STARR-seq-based MPRA, designated HDI-STARR-seq (PMID:39716078) to determine condition-specific enhancer activity in mouse liver at scale. Analysis of a synthetic STARR-seq library, comprised of 23,912 reporters regions spanning 1839 ATAC regions enabled functional assessment of mouse liver enhancer activity in vivo across three distinct biological conditions: male iver, feamle liver and continuous growth hormone (GH)-infused male liver, which is substantially feminized with regards to gene expression. HDI-STARR-seq reporters representing 305 ATAC regions showed sex-biased and GH-responsive enhancer activity that mirrored the regulation of their chromatin accessibility in hepatocytes, validating these sites as functional, physiologically regulated enhancers. These enhancers were enriched for activating histone marks (H3K4me1, H3K27ac) and for binding sites for GH-activated transcriptional regulator STAT5 and for the STAT5-dependent, sex-specific repressors BCL6 and CUX2, consistent with a cohesive regulatory network controlling hepatocyte lipid and xenobiotic metabolism. Further, de novo motif analysis identified binding sites for HNF4A and for several novel factors specifically enriched at the regulated enhancers. Importantly, sex-biased and GH-regulated functional enhancers were linked to both MASLD (metabolic dysfunction-associated steatotic liver disease)-enabling and MASLD-protective genes, indicating that GH-dependent chromatin remodeling at these loci is a key determinant of sex-differential liver metabolic disease susceptibility. This integrated in vivo approach defines a validated set of GH-regulated hepatocyte enhancers through which chromatin accessibility and transcription factor binding drive sexual dimorphism in hepatic metabolism and sex-specific MASLD risk. Overall design: We implemented the synthetic STARR-seq library in control male liver, control female liver and cGH-treated male liver to quantitatively measure intrinsic transcription activity in the corresponding group. A pool of chemically-synthetic DNA fragments in 210 nt length were amplified and delivered to untreated adult male CD-1 mice, untreated adult female CD-1 mice,and 10d cGH-treated male male using osmotic pump. A pooled plasmid library was delivered into mice using hydrodynamic tail vein injection (HDI) for in vivo transfection, preferentially for livers. For a STARR-seq library, three types of sequencing libraries incorporated in this submission (i.e., STARR-seq plasmid libraries, STARR-seq DNA libraries and STARR-seq RNA libraries) are generated by PCR amplification using the same PCR condition. The STARR-seq plasmid library, which is the same material injected in HDI livers, represents the abundance of each reporter assaying DNaseI digested regions in response to sex-specific open chromatin regions or TCPOBOP-responsive open chromatin regions. DNA plasmids extracted from a small piece of HDI livers were amplified using DNA reporter-specific primers, and represented the intake plasmids in livers. The read counts of each reporter were used as denominator to calculate STARR-seq enhancer activity. Poly-adenylated RNA plasmids extracted from HDI livers were reverse-transcribed followed by DNase treatment, and amplified using RNA reporter-specific primers, and represented the self-transcribing activity of the DHS. The read counts of each reporter were used as numerator to calculate STARR-seq enhancer activity.