Structure and localization of the IGFBP-1 gene and its expression during liver regeneration.

Insulin-like growth factor-binding protein-1s are important modulators of the insulin-like growth factors that may have both positive and negative effects on the ability of insulin-like growth factors to stimulate cell growth. The IGFBP-1 gene is one of the most highly induced immediate-early genes after partial hepatectomy. The IGFBP-1 gene is also expressed at a high level during fetal liver development and in response to nutritional changes and diabetes. Therefore it may have important roles in liver growth and metabolism. To begin to examine the regulation of this gene, we cloned and sequenced the entire mouse IGFBP-1 gene. Its structure is highly similar to that of the human gene, and, in addition to the exonic regions, the two genes are highly conserved in specific regions in the promoter and first intron. Analysis of this conservation allows us to predict important regulatory sites that define the tissue specific and insulin-mediated regulation of the gene and identify potential sites that might be important for the transcriptional induction during liver regeneration. The mouse gene is located on mouse chromosome 11; it is found at the boundary between regions in the mouse genome homologous to human chromosomes 22 and 7. We found IGFBP-1 mRNA in both parenchymal and nonparenchymal RNA after partial hepatectomy. Using in situ hybridization of IGFBP-1 mRNA in regenerating rat liver tissue, we demonstrated IGFBP-1 transcripts in several cell types. We found that IGFBP-1 gene induction after partial hepatectomy is paralleled by protein expression.(ABSTRACT TRUNCATED AT 250 WORDS)

Novel delayed-early and highly insulin-induced growth response genes. Identification of HRS, a potential regulator of alternative pre-mRNA splicing.

We have identified 41 novel and many previously known growth response genes induced in regenerating liver and insulin-treated Reuber H35 cells, a rat hepatoma cell line that grows in response to physiologic concentrations of insulin and retains some properties of regenerating liver. Although many genes are expressed similarly in the two systems, there are important differences in the kinetics of induction of some genes. These differences allowed us to identify and characterize novel genes that are highly insulin-induced and expressed as delayed-early genes in regenerating liver. Sequence analysis of CL-6, the most abundant insulin-induced gene, resulted in the identification of a highly hydrophobic hepatic protein. Sequence analysis of HRS, a highly insulin-induced delayed-early gene, demonstrated that it is a member of the family of regulators of alternative pre-mRNA splicing. Different forms of HRS mRNA are temporally regulated during the growth response, suggesting that HRS could autoregulate processing of its pre-mRNA. Given the dramatic increase in RNA production during late G1, proteins induced by mitogens like insulin that control RNA processing are likely to have important roles in cell cycle regulation.

Induction patterns of 70 genes during nine days after hepatectomy define the temporal course of liver regeneration.

Liver regeneration is an important process that allows for recovery from hepatic injuries caused by viruses, toxins, ischemia, surgery, and transplantation. Previously, we identified > 70 immediate-early genes induced in regenerating liver after hepatectomy, 41 of which were novel. While it is expected that the proteins encoded by these genes may have important roles in regulating progression through the G1 phase of the cell cycle during regeneration, we were surprised to note that many of these "early" genes are expressed for extended periods during the hepatic growth response. Here we define several patterns of expression of immediate-early, delayed-early, and liver-specific genes during the 9-d period after hepatectomy. One pattern of induction parallels the major growth period of the liver that ends at 60-72 h after hepatectomy. A second pattern has two peaks coincident with the first and second G1 phases of the two hepatic cell cycles. A third group, which includes liver-specific genes such as C/EBP alpha, shows maximal expression after the growth period. Although the peak in DNA synthesis in nonparenchymal cells occur 24 h later than in hepatocytes, most of the genes studied demonstrate similar induction in both cell types. This finding suggests that the G0/G1 transition occurs simultaneously in all cells in the liver, but that the G1 phase of nonparenchymal cells may be relatively prolonged. Finally, we examined the expression of > 70 genes in clinical settings that could induce liver regeneration, including after perfusion in a donor liver, hepatic ischemia, and fulminant hepatic failure. We found that a small number of early and liver-specific genes were selectively activated in human livers under these conditions, and we thereby provide a potential means of measuring the caliber of the regenerative response in clinical situations.

Rapid induction in regenerating liver of RL/IF-1 (an I kappa B that inhibits NF-kappa B, RelB-p50, and c-Rel-p50) and PHF, a novel kappa B site-binding complex.

The liver is one of the few adult tissues that has the capacity to regenerate following hepatectomy or toxic damage. In examining the early growth response during hepatic regeneration, we found that a highly induced immediate-early gene in regenerating liver encodes RL/IF-1 (regenerating liver inhibitory factor) and is the rat homolog of human MAD-3 and probably of chicken pp40. RL/IF-1 has I kappa B activity of broad specificity in that it inhibits the binding of p50-p65 NF-kappa B, c-Rel-p50, and RelB-p50, but not p50 homodimeric NF-kappa B, to kappa B sites. Like RL/IF-1, several members of the NF-kappa B and rel family of transcription factors are immediate-early genes in regenerating liver and mitogen-treated cells. We examined changes in kappa B site binding activity during liver regeneration and discovered a rapidly induced novel kappa B site-binding complex designated PHF [posthepatectomy factor(s)]. PHF is induced over 1,000-fold within minutes posthepatectomy in a protein synthesis-independent manner, with peak activity at 30 min, and is not induced by sham operation. PHF is distinct from p50-p65 NF-kappa B, which is present only in the inactive form in liver posthepatectomy. Although early PHF complexes do not interact strongly with anti-p50 antibodies, PHF complexes present later (3 to 5 h) posthepatectomy react strongly, suggesting that they contain a p50 NF-kappa B subunit. Unlike p50-p65 NF-kappa B, c-Rel-p50, and RelB-p50 complexes, PHF binding to kappa B sites is not inhibited by RL/IF-1. One role of RL/IF-1 in liver regeneration may be to inhibit p50-p65 NF-kappa B activity present in hepatic cells, allowing for the preferential binding of PHF to kappa B sites. Because PHF is induced immediately posthepatectomy in the absence of de novo protein synthesis, PHF could have a role in the regulation of liver-specific immediate-early genes in regenerating liver.

Identification of LRF-1, a leucine-zipper protein that is rapidly and highly induced in regenerating liver.

Liver regeneration provides one of the few systems for analysis of mitogenesis in the fully developed, intact animal. Several proteins have been identified as part of the primary growth response in regenerating liver and in mitogen-stimulated cells. Some of these proteins, such as the Jun and Fos families of transcription factors, are thought to have a role in activating transcription of genes expressed subsequently in the growth response. Through differential screening of a regenerating-liver cDNA library, we have identified a rapidly and highly induced gene encoding a 21-kDa leucine-zipper-containing protein that we have designated liver regeneration factor 1 (LRF-1). LRF-1 has no homology with other leucine-zipper proteins outside the basic and leucine-zipper domains. LRF-1 alone can bind DNA, but it preferentially forms heteromeric complexes with c-Jun and Jun-B and does not interact with c-Fos. In solution, it binds with highest affinity to cAMP response elements but also has affinity for related sites. In cotransfection studies, LRF-1 in combination with c-Jun strongly activates a c-Jun-responsive promoter. The induction of the LRF-1 gene in regenerating liver greatly increases the potential variety of heterodimeric combinations of leucine-zipper transcription factors. While LRF-1 mRNA is rapidly induced in the absence of protein synthesis, its peak induction is later than c-fos mRNA, suggesting that LRF-1 may regulate responsive genes at a later point in the cell cycle. As such, LRF-1 may have a unique and critical role in growth regulation of regenerating liver and mitogen-stimulated cells.

The gene encoding rat insulinlike growth factor-binding protein 1 is rapidly and highly induced in regenerating liver.

The liver is an epithelioid organ that can regenerate following partial hepatectomy. Although it is composed mainly of hepatocytes, it has a complex, multicellular architecture, implying that intercellular communications must exist during regeneration. As in other mitogen-stimulated cells, immediate-early growth response genes induced in the absence of prior protein synthesis are likely to play an important regulatory role in the regenerative process. Through differential screening of regenerating liver cDNA libraries, we found that one of the most highly expressed immediate-early genes in liver regeneration encodes the rat homolog of the low-molecular-weight insulinlike growth factor (IGF)-binding protein (IGFBP-1). This protein has been implicated in enhancing the mitogenic effect of IGF on tissues. IGFBP-1 gene induction is transcriptionally mediated and specific to regenerating liver, as the gene is not expressed in mitogen-stimulated fibroblasts. IGFBP-1 expression has been shown to increase under low-insulin conditions such as diabetes, and the complex regulation of expression is indicated by our finding that insulin treatment of H35 rat hepatoma cells, which induces proliferation, also causes a rapid decrease in transcription and expression of the IGFBP-1 gene. Of note, IGFBP-1 mRNA is abundant in fetal rat liver, implying that it participates in normal liver growth and development. Although regenerating liver cells continue to produce IGF-I, we did not detect IGF-I receptor mRNA during the first 24 h after hepatectomy. However, some IGFBPs may act to enhance the activity of IGF-I independently of IGF-I receptors. Thus, IGF-1 and IGFBPs may interact with hepatocytes or nonparenchymal liver cells, through either IGF-I or novel receptors. In this way, IGFBP-I and IGF-I could act in a paracrine and/or autocrine fashion in maintaining normal liver architecture during regeneration.

The immediate-early growth response in regenerating liver and insulin-stimulated H-35 cells: comparison with serum-stimulated 3T3 cells and identification of 41 novel immediate-early genes.

Liver regeneration provides a unique system for analysis of mitogenesis in intact, fully developed animals. Cellular immediate-early genes likely play an important role in cell cycle regulation and have been extensively studied in mitogen-stimulated fibroblasts lymphocytes but not in liver. We have begun to characterize the immediate-early growth response genes of mitogen-stimulated liver cells, specifically, regenerating liver and insulin-stimulated Reuber H-35 hepatoma cells, and to address differences in growth response between different cell types. Through subtraction and differential screening of cDNA libraries from regenerating liver and insulin-treated H-35 cells, we have extensively characterized 341 differentially expressed clones and identified 52 immediate-early genes. These genes have been partially sequenced and subjected to Northern (RNA) blot analysis, and 41 appear to be novel. Surprisingly, two-thirds of these genes are also expressed in BALB/c 3T3 cells, but only 10 were identified in previous studies of 3T3 cells, and of these, 6 include well-known genes like jun and fos, and only 4 are novel. Approximately one-third of the immediate-early genes identified in mitogen-stimulated liver cells or serum-stimulated NIH 3T3 cells are expressed in a tissue-specific fashion, indicating that cell type-specific regulation of the proliferative response occurs during the immediate-early period. Our findings indicate that the immediate-early response is unusually complex for the first step in a regulatory cascade, suggesting that multiple pathways must be activated. The abundance of immediate-early genes and the highly varied pattern of their expression in different cell types suggest that the tissue specificity of the proliferative response arises from the particular set of these genes expressed in a given tissue.

Immediate-early gene expression differs between regenerating liver, insulin-stimulated H-35 cells, and mitogen-stimulated Balb/c 3T3 cells. Liver-specific induction patterns of gene 33, phosphoenolpyruvate carboxykinase, and the jun, fos, and egr families.

Immediate-early genes, whose expression increases independent of de novo protein synthesis during the transition from quiescence to proliferation, are postulated to play important regulatory roles in the growth response. The complement of immediate-early genes expressed must depend on the milieu of preexisting transcription factors in the quiescent cell as well as the type of mitogenic stimulation and, thus, may differ between cell types. We have begun characterizing the immediate-early response in regenerating liver and insulin-stimulated Reuber H-35 hepatoma cells in comparison with previously published results from mitogen-stimulated Balb/c 3T3 fibroblasts. The proliferating H-35 and regenerating liver cells maintain their similarity to quiescent liver as demonstrated by their continued production of the liver-specific albumin, CCAAT/enhancer binding protein, and phosphoenolpyruvate carboxykinase messenger RNAs (mRNA). Surprisingly, the phosphoenolpyruvate carboxykinase gene, which undergoes down-regulation in insulin-treated H-35 cells, was cloned by differential screening of a subtraction-enriched regenerating liver cDNA library and is an immediate-early gene in regenerating liver. H-35 cells treated with either insulin or phorbol 12-myristate 13-acetate express elevated levels of the jun genes, and phorbol 12-myristate 13-acetate pretreatment fails to abolish the insulin response, indicating that it does not depend on protein kinase C. jun family gene expression in regenerating liver differs from that in mitogen-treated fibroblasts in that the time course of expression of c-jun and junB is prolonged, and junD mRNA levels distinctly increase. Additionally, although c-fos and egr-1 mRNAs are expressed at elevated levels in stimulated liver cells, fos-B, fra-1, and egr-2 are not, which suggests that factors in addition to the serum response factor participate in the regulation of immediate-early gene induction. Interestingly, gene 33, which was cloned from a regenerating liver cDNA library by differential screening and lacks a recognizable serum response element, functions as an immediate-early gene in regenerating liver and in mitogen-treated H-35 and Balb/c 3T3 cells. These results suggest that gene 33 participates in the transition from quiescence to proliferation in many mitogen-treated cells in addition to its previously reported involvement in hormone responses. Overall, the results presented here suggest that the immediate-early response varies considerably between regenerating liver and mitogen-stimulated fibroblasts and could involve multiple, preexisting, tissue-specific, transcription-activating proteins.