Genomic organization and promoter characterization of two human UHS keratin genes

Positive selection, relaxation, and acceleration in the evolution of the human and chimp genome

For years evolutionary biologists have been interested in searching for the genetic bases underlying humanness. Recent efforts at a large or a complete genomic scale have been conducted to search for positively selected genes in human and in chimp. However, recently developed methods allowing for a more sensitive and controlled approach in the detection of positive selection can be employed. Here, using 13,198 genes, we have deduced the sets of genes involved in rate acceleration, positive selection, and relaxation of selective constraints in human, in chimp, and in their ancestral lineage since the divergence from murids. Significant deviations from the strict molecular clock were observed in 469 human and in 651 chimp genes. The more stringent branch-site test of positive selection detected 108 human and 577 chimp positively selected genes. An important proportion of the positively selected genes did not show a significant acceleration in rates, and similarly, many of the accelerated genes did not show significant signals of positive selection. Functional differentiation of genes under rate acceleration, positive selection, and relaxation was not statistically significant between human and chimp with the exception of terms related to G-protein coupled receptors and sensory perception. Both of these were over-represented under relaxation in human in relation to chimp. Comparing differences between derived and ancestral lineages, a more conspicuous change in trends seems to have favored positive selection in the human lineage. Since most of the positively selected genes are different under the same functional categories between these species, we suggest that the individual roles of the alternative positively selected genes may be an important factor underlying biological differences between these species.

Since the publication of the human and the chimp genomes, one of the major challenges in evolutionary biology has begun to be deciphered: namely, the search for positively selected genes that have shaped humanness. Arbiza and colleagues undertake a genomic-scale search for the genes that have been positively selected in human, in chimp, and in their common ancestral lineage. They conclude that events of positive selection were six times more frequent in chimp than in human, although they do not group under specific functional classes that have been preferentially selected in either species. However, in the comparisons of the evolutionary trends between the ancestral and the descendant lineages, they found that most of the relative differences in common classes show an abundance of positive selection on the human branch. By differentiating positive selection from a relaxation of selective constraints, both producing analogous footprints in the genome, they demonstrate that many of the genes previously thought to have been positively selected correspond to likely cases of relaxation. Finally, they quantify the bias produced by the use of average rate–based approaches to concentrate cases of adaptive evolution in these species.

Human hair keratin-associated proteins (KAPs)

Elucidation of the genes encoding structural proteins of the human hair follicle has advanced rapidly during the last decade, complementing nearly three previous decades of research on this subject in other species. Primary among these advances was both the characterization of human hair keratins, as well as the hair keratin associated proteins (KAPs). This review describes the currently known human KAP families, their genomic organization, and their characteristics of expression. Furthermore, this report delves into further aspects, such as polymorphic variations in human KAP genes, the role that KAP proteins might play in hereditary hair diseases, as well as their modulation in several different transgenic mouse models displaying hair abnormalities.

Identification of two novel clusters of ultrahigh-sulfur keratin-associated protein genes on human chromosome 11

We analyzed two novel clusters of keratin-associated protein (KAP) genes on human chromosome 11 (11p15.5 and 11q13.5) in which we identified two known human KRTAP5 genes, KerA (=KRN1) and KerB, and nine novel KRTAP5 family genes. RT-PCR analysis of these KAP genes showed preferential expression in human hair root, suggesting these gene products are required for hair formation. Based on the deduced amino acid sequences, all these KAP proteins were classified into an ultrahigh-sulfur (UHS) type KAP with high cysteine content (> 30 mol%). These KAPs also showed high glycine and serine contents (average 24.30 and 21.13 mol%, respectively), distinguishing from other UHS/HS KAP families located on human chromosomes 17 and 21. Dot-matrix analysis revealed a significant similarity between these two KAP gene clusters. We postulated a mechanism by which these two KAP gene clusters are generated via genomic duplication of a primordial gene cluster followed by genetic modification during evolution.

Hair Keratin Associated Proteins: Characterization of a Second High Sulfur KAP Gene Domain on Human Chromosome 2111In fond memory of Dr Peter Steinert

Analysis of the EBI/GeneBank database using nonhuman hair keratin associated protein (KAP) gene sequences as a query resulted in the identification of two human KAP gene domains on chromosome 21, one of which, located at 21q22.1, has recently been characterized. The second domain presented here, an approximately 90 kb domain on chromosome 21q23, harbored 16 KAP genes and two KAP pseudogenes. By comparison with known sheep and mouse KAP families, these genes could be assigned to two KAP families, KAP10 and KAP12, with the KAP10 family (12 members) being distinctly larger than the KAP12 family (four members). Systematic cDNA/3' rapid amplification of cDNA ends isolation studies using human scalp mRNA led to the identification of eight KAP10 and two KAP12 cDNA sequences. In situ hybridization analyses of human anagen hair follicles using specific 3'-noncoding sequences of the various KAP10/KAP12 genes revealed mRNA expression of nearly all KAP10 and KAP12 members exclusively in a narrow region of the middle portion of the hair fiber cuticle. Bioinformatic analyses of the promoter regions of the KAP10/KAP12 genes demonstrated several enhancer elements that were present in nearly all of the KAP genes. Primary among these were binding elements for the ETS, heat shock factor, AML, and HOX families of transcription factors.

Characterization of human keratin-associated protein 1 family members

Keratin-associated proteins are involved in the formation of the cross-linked network of the keratin-intermediate filament proteins that support hair fibers. In recent years, several keratin-associated protein genes have been identified and become an attractive topic in hair research. More recently, we isolated two cDNA encoding novel members of the human keratin-associated protein 1 family (human keratin-associated protein 1.6 and human keratin-associated protein 1.7), and described their expression in the hair follicle by RNA in situ hybridization. A comparison of human keratin-associated protein 1.6 and human keratin-associated protein 1.7 with other human keratin-associated protein 1 members revealed that keratin-associated protein 1 proteins are fundamentally composed of five distinct domains, and that they can be classified primarily by a striking variation in double cysteine-containing pentapeptide repeats in the repetitive I domain. The sum of the data analyzed suggests that human keratin-associated protein 1 family genes may have arisen mainly through gene duplication of the cysteine-repeat motifs during evolution.

Characterization of a first domain of human high glycine-tyrosine and high sulfur keratin-associated protein (KAP) genes on chromosome 21q22.1

Analysis of the EBI/GeneBank(TM) data base using non-human hair keratin-associated protein (KAP) cDNA sequences as a query resulted in the identification of a first domain of high glycine-tyrosine and high sulfur KAP genes located on human chromosome 21q22.1. This domain, present on the DNA accession numbers and, was approximately 535 kb in size and contained 17 high glycine-tyrosine and 7 high sulfur KAP genes, as well as 9 KAP pseudogenes. Based on amino acid sequence comparisons of the encoded proteins, the KAP genes could be divided into seven high glycine-tyrosine gene families (KAP6-KAP8, and KAP19-KAP22) and four high sulfur gene families (KAP11, KAP13, KAP15, and KAP23). The high glycine-tyrosine genes described here appear to represent the complete set of this type of KAP genes present in the human genome. Both systematic cDNA isolation studies from an arrayed scalp cDNA library and in situ hybridization expression studies of all of the KAP genes identified in the 21q22.1 region revealed varying degrees and regions of expression of 11 members of the high tyrosine-glycine genes and 6 members of the high sulfur KAP genes in the hair forming compartment.

Polymorphisms in the human high sulfur hair keratin-associated protein 1, KAP1, gene family

Hair fiber differentiation and maturation involves the close interaction between hair keratins and their associated proteins, KAPs. Recently, a cluster of seven human KAP multigen families has been identified on chromosome 17q12-21 among which were four hKAP1 genes (hKAP1.1B, hKAP1.3, hKAP1.4, and hKAP1.5). In addition, there were previous as well as recent reports on four additional hKAP1 genes (hKAP1.1A, hKAP1.2, hKAP1.6, and hKAP1.7) with unknown chromosomal location. In this study, we have analyzed these eight hKAP1 genes in unrelated Japanese and Caucasian individuals and discovered that hKAP1.1A, hKAP1.6, and hKAP1.7 represent size polymorphisms of the hKAP1.1B gene. In addition, we show that hKAP1.2 as well as three hitherto unknown genes (hKAP1.8A, hKAP1.8B, and hKAP1.9) are size polymorphisms of the hKAP1.3 gene. In contrast, no polymorphic alleles were found for the hKAP1.4 and hKAP1.5 genes. We provide evidence that the polymorphic hKAP1.1B and hKAP1.3 alleles arose mainly by intragenic deletion and/or duplication events of distinct pentapeptide repeats typical for hKAP1 genes. We also demonstrate the occurrence of both frequent and rare population-specific hKAP1.1B and hKAP1.3 alleles, which were obviously generated after the divergence of the Caucasian and Japanese lineage. In addition, by means of a pan-hKAP1 antibody, we confirm the previous hKAP1 family mRNA localization data in the middle to upper cortex of the human anagen hair follicle.

hKAP1.6 and hKAP1.7, two novel human high sulfur keratin-associated proteins are expressed in the hair follicle cortex

Hair fiber differentiation involves the expression of both hair keratin intermediate filament proteins and their associated proteins, termed keratin-associated proteins. In this study, cDNA clones encoding two novel keratin-associated proteins were isolated from human hair follicle mRNA. The predicted amino acid sequence derived from these clones revealed that these proteins represent members of the human keratin-associated protein 1 family. They show strong sequence homology to two previously described keratin-associated protein 1 family members hKAP1.1 A and hKAP1.1B. We have called these new proteins hKAP1.6 and hKAP1.7, respectively. RNA in situ hybridization studies of human anagen hair follicles using a conserved probe for these four keratin-associated protein 1 members demonstrated the expression of this group in the differentiated portions of the hair cortex.

Characterization of a cluster of human high/ultrahigh sulfur keratin-associated protein genes embedded in the type I keratin gene domain on chromosome 17q12-21

Low stringency screening of a human P1 artificial chromosome library using a human hair keratin-associated protein (hKAP1.1A) gene probe resulted in the isolation of six P1 artificial chromosome clones. End sequencing and EMBO/GenBank(TM) data base analysis showed these clones to be contained in four previously sequenced human bacterial artificial chromosome clones present on chromosome 17q12-21 and arrayed into two large contigs of 290 and 225 kilobase pairs (kb) in size. A fifth, partially sequenced human bacterial artificial chromosome clone data base sequence overlapped and closed both of these contigs. One end of this 600-kb cluster harbored six gene loci for previously described human type I hair keratin genes. The other end of this cluster contained the human type I cytokeratin K20 and K12 gene loci. The center of the cluster, starting 35 kb downstream of the hHa3-I hair keratin gene, contained 37 genes for high/ultrahigh sulfur hair keratin-associated proteins (KAPs), which could be divided into a total of 7 KAP multigene families based on amino acid homology comparisons with previously identified sheep, mouse, and rabbit KAPs. To date, 26 human KAP cDNA clones have been isolated through screening of an arrayed human scalp cDNA library by means of specific 3'-noncoding region polymerase chain reaction probes derived from the identified KAP gene sequences. This screening also yielded four additional cDNA sequences whose genes were not present on this gene cluster but belonged to specific KAP gene families present on this contig. Hair follicle in situ hybridization data for single members of five different KAP multigene families all showed localization of the respective mRNAs to the upper cortex of the hair shaft.

Identification of ICR170-induced XPD mutations in UV-sensitive CHO cells

We highlight selected contributions of Dr. Richard Setlow that contributed to our earlier understanding of excision repair processes and set the stage for dissecting nucleotide excision repair (NER) in mammalian cells through molecular genetics. More than 20 years ago, large-scale screens for UV-sensitive mutants of hamster CHO cells isolated approximately 200 mutants, many of which were assigned to the XPD/ERCC2 complementation group, but the nature of the mutations was not determined. The XPD protein performs not only an essential viability function as a structural component of transcription initiation factor TFIIH, but also an NER function as a 5' to 3' DNA helicase within TFIIH that unwinds DNA on the 3' side of bulky lesions. Alterations in these XPD functions are responsible for three UV-sensitivity genetic disorders that have distinguishable clinical features. In this study, we sequenced six UV-sensitive ICR170-induced Chinese hamster ovary (CHO) cell mutants that previously were assigned to the XPD complementation group to determine whether they carry frameshift mutations. All six mutants show 3- to 5-fold increased hypersensitivity to UV irradiation, similar to the XPD mutant prototype UV5. Even though ICR170 is a strong frameshift mutagen, all six cell lines contain base substitution mutations, five of which are unique among all mutations identified so far in human and rodent cells. The sixth mutation was identical to the R75W mutation previously found in CHO UVL-1. The results presented here contribute to a mutation database that should prove useful in structure-function studies of this unique DNA-structure-specific helicase and its complex mutant phenotypes.