Organization and expression of the human serpin gene cluster at 14q32.1.

The serpins are a superfamily of gene sequences that have been conserved through evolution. These genes encode protein products that perform a variety of functions in vivo, and their regulation differs among different cell types. About one-third of the serpin genes in the human genome are located at 14q32.1, and the serpin genes in this ~370 kb region are organized into discrete proximal, central, and distal subclusters of four, three, and four genes each. In this report we discuss the genomic organization of the 14q32.1 serpin gene cluster, and we summarize what is known about the regulation of each serpin gene in this region. An approach for studying locus-wide regulation of chromosomal serpin genes in situ is also described. Using this approach, specific mutations in the proximal serpin subcluster were prepared by homologous recombination. These mutant alleles define a serpin locus control region that regulates gene activity and chromatin structure of the entire proximal subcluster. Prospects for further analyses of this complex genomic domain are discussed.

Sequence organization and matrix attachment regions of the human serine protease inhibitor gene cluster at 14q32.1.

The human serine protease inhibitor (serpin) gene cluster at 14q32.1 is a useful model system for studying the regulation of gene activity and chromatin structure. We demonstrated previously that the six known serpin genes in this region were organized into two subclusters of three genes each that occupied approximately 370 kb of DNA. To more fully understand the genomic organization of this region, we annotated a 1-Mb sequence contig from data from the Genoscope sequencing consortium (http://www.genoscope.cns.fr/ ). We report that 11 different serpin genes reside within the 14q32.1 cluster, including two novel alpha1-antiproteinase-like gene sequences, a kallistatin-like sequence, and two recently identified serpins that had not been mapped previously to 14q32.1. The genomic regions proximal and distal to the serpin cluster contain a variety of unrelated gene sequences of diverse function. To gain insight into the chromatin organization of the region, sequences with putative nuclear matrix-binding potential were identified by using the MAR-Wiz algorithm, and these MAR-Wiz candidate sequences were tested for nuclear matrix-binding activity in vitro. Several differences between the MAR-Wiz predictions and the results of biochemical tests were observed. The genomic organization of the serpin gene cluster is discussed.

Chromosomal elements regulate gene activity and chromatin structure of the human serpin gene cluster at 14q32.1.

The human serine protease inhibitor (serpin) gene cluster at 14q32.1 contains a number of genes that are specifically expressed in hepatic cells. Cell-specific enhancers have been identified in several of these genes, but elements involved in locus-wide gene and chromatin control have yet to be defined. To identify regulatory elements in this region, we prepared a series of mutant chromosomal alleles by homologous recombination and transferred the specifically modified human chromosomes to hepatic cells for functional tests. We report that deletion of an 8-kb DNA segment upstream of the human alpha1-antitrypsin gene yields a mutant serpin allele that fails to be activated in hepatic cells. Within this region, a 2.3-kb DNA segment between kb -8.1 and -5.8 contains a previously unrecognized control region that is required not only for serpin gene activation but also for chromatin remodeling of the entire locus.