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editorial
. 2006 Jul 17;174(2):169–174. doi: 10.1083/jcb.200603161

New consensus nomenclature for mammalian keratins

Jürgen Schweizer 1, Paul E Bowden 3, Pierre A Coulombe 4, Lutz Langbein 2, E Birgitte Lane 5, Thomas M Magin 6, Lois Maltais 7, M Bishr Omary 8, David AD Parry 9, Michael A Rogers 1, Mathew W Wright 10
PMCID: PMC2064177  PMID: 16831889

Abstract

Keratins are intermediate filament–forming proteins that provide mechanical support and fulfill a variety of additional functions in epithelial cells. In 1982, a nomenclature was devised to name the keratin proteins that were known at that point. The systematic sequencing of the human genome in recent years uncovered the existence of several novel keratin genes and their encoded proteins. Their naming could not be adequately handled in the context of the original system. We propose a new consensus nomenclature for keratin genes and proteins that relies upon and extends the 1982 system and adheres to the guidelines issued by the Human and Mouse Genome Nomenclature Committees. This revised nomenclature accommodates functional genes and pseudogenes, and although designed specifically for the full complement of human keratins, it offers the flexibility needed to incorporate additional keratins from other mammalian species.

What's in a name? That which we call a rose, by any other name would smell as sweet (Romeo and Juliet, Act II, Sc. ii).

Keratins (previously also called cytokeratins) are filament-forming proteins of epithelial cells and are essential for normal tissue structure and function. Keratin genes account for most of the intermediate filament genes in the human genome, making up the two largest sequence homology groups, type I and II, of this large multigene family. They are highly differentiation-specific in their expression patterns, implying functional differences. Mutations in most of them are now associated with specific tissue-fragility disorders, and antibodies to keratins are important markers of tissue differentiation and, therefore, tools in diagnostic pathology. Since the first keratins were sequenced and identified as type I and II intermediate filament proteins, the increasing numbers of keratins has provided an ongoing challenge for their clear identification and logical classification across species.

The first attempt at providing a comprehensive keratin nomenclature dates back to 1982. Moll et al. (1982) used 2D isoelectric focusing and SDS-PAGE to map the keratin profiles of a large number of normal human epithelia, tumors, and cultured cells. They grouped the basic-to-neutral type II keratins as K1–K8 and the acidic type I keratins as K9–K19 (Moll et al., 1982). Although not open-ended for type II keratins, this system has so far proven manageable, as the incorporation of a few novel type II keratins could be accomplished by the addition of discriminatory suffix letters to keratins exhibiting similar gel-electrophoretic properties (Collin et al., 1992a,b; Winter et al., 1998). Moreover, the Moll nomenclature has not been further challenged by the “hard” α-keratins of hair and nail (hair keratins), as these keratins were named Ha (acidic, type I) or Hb (basic to neutral, type II) followed by a number, with H standing for hair (Heid and Franke, 1986; Rogers et al., 1998, 2000). Overall, however, the present naming of keratins has not been systematic, and a reorganized and durable scheme is long overdue.

Genome analyses have recently demonstrated that humans possess a total of 54 functional keratin genes, i.e., 28 type I and 26 type II keratins, forming two clusters of 27 genes each on chromosomes 17q21.2 and 12q13.13 (the gene for the type I keratin K18 being located in the type II keratin gene domain; Hesse et al., 2001, 2004; Rogers et al., 2004, 2005; Table I). Recognition of the extent of this large mammalian gene family led to a suggested revised nomenclature (Hesse et al., 2004) based on an extended Moll system, K1–K8, and K9–K24 (Moll et al., 1982, 1990 ; Chandler et al., 1991; Zhang et al., 2001; Sprecher et al., 2002), and conceptually close to an earlier proposal (Rogers and Powell, 1993). In this nomenclature, all human type I keratins were named Ka9 to KaX and all type II keratins were named Kb1 to KbY, thus, enabling type I and II keratins of other mammalian species to be added consecutively into this open-ended system. At the 2004 Gordon Conference on Intermediate Filaments in Oxford, an initiative to achieve international consensus led to the formation of a broad-based Keratin Nomenclature Committee that included active investigators in the keratin field and members of the Human Genome Nomenclature Committee (HGNC) and the Mouse Genome Nomenclature Committee. This committee evaluated several potential nomenclature schemes and, after extensive deliberation and consultation with other colleagues in the intermediate filament field, arrived at the consensus nomenclature system that is detailed in the following sections.

Table I.

Human keratin genes

Human keratin genes Type I genes Type II genes
Total genes 33 34
Functional genes 28 26
Pseudogenes 5 8
Epithelial keratin genes 17 20
Hair keratin genes 11 6
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To structure the new nomenclature system, the 54 human keratins and their genes are divided into three categories: (1) epithelial keratins/genes, (2) hair keratins/genes, and (3) keratin pseudogenes. The nomenclature is also structured to allow for the inclusion of a fourth category of nonhuman epithelial and hair keratins of other mammalian species, whose genes are either absent or occur as pseudogenes in the human genome.

For both type I and II keratins, these four categories are numerically arranged in the following order (Table II): (1) human epithelial keratins, (2) human hair keratins, (3) nonhuman epithelial/hair keratins, and (4) human keratin pseudogenes.

Table II.

Numbering scheme of keratin categories

Category Number range
Human type I epithelial keratins 9–28
Human type I hair keratins 31–40
Nonhuman type I epithelial and hair keratins 41–70
Human type II epithelial keratins 1–8 and 71–80
Human type II hair keratins 81–86
Nonhuman type II epithelial and hair keratins 87–120
Type II keratin pseudogene 121–220
Type I keratin pseudogenes 221 →
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Because of historical reasons and the extensive number of existing publications, the Moll designation for the epithelial keratins K1–K8 and K9–K24 (Moll et al., 1982, 1990; Chandler et al., 1991; Zhang et al., 2001; Sprecher et al., 2002) is retained, as is the existing HGNC gene designation scheme (i.e., KRT#).

New nomenclature for type I keratins Human epithelial keratins

After the classical type I epithelial keratins K9–K24, the numbers 25–28 were consecutively assigned to the four recently identified epithelial keratins K25irs1–4, which are differentially expressed in the inner root sheath of the human hair follicle (Bawden et al., 2001; Rogers et al., 2004). Thus, the numbers 9–28 represent the 17 human type I epithelial keratins and their genes (Tables I, II, and III [columns 4 and 5]). Numbers 11, 21, and 22 are unused for historical reasons. K11, for example, was originally thought to be a unique gene product (Moll et al., 1982), but was later confirmed as a polymorphic variant of K10 (Korge et al., 1992; Mischke, 1998). K21 (Chandler et al., 1991) has now been shown to be a rat orthologue for human and mouse K20 (Moll et al., 1993; Zhou et al., 2003), and it has therefore been removed from the category of human type I epithelial keratins. Position number 22 was previously reserved by the HGNC, but has never been used.

Table III.

Type I keratins

Current protein
designation		 Current gene
designation		 Protein designation according to
Hesse et al., 2004 a 		New protein
designation		 New gene
designation
Human epithelial keratins
    K9 KRT9 Ka9 K9 KRT9
    K10 KRT10 Ka10 K10 KRT10
    K12 KRT12 Ka12 K12 KRT12
    K13 KRT13 Ka13 K13 KRT13
    K14 KRT14 Ka14 K14 KRT14
    K15 KRT15 Ka15 K15 KRT15
    K16 KRT16 Ka16 K16 KRT16
    K17 KRT17 Ka17 K17 KRT17
    K18 KRT18 Ka18 K18 KRT18
    K19 KRT19 Ka19 K19 KRT19
    K20 KRT20 Ka20 K20 KRT20
    K21 rat no designation
    K23 KRT23 Ka23 K23 KRT23
    K24 KRT24 Ka24 K24 KRT24
    K25irs1b, K10Cc, hIRSa1d KRT25A Ka38 K25 KRT25
    K25irs2b, K10Dc KRT25B Ka39 K26 KRT26
    K25irs3b, K10Bc, hIRSa3.1d KRT25C Ka40 K27 KRT27
    K25irs4b, hIRSa2d KRT25D Ka41 K28 KRT28
Human hair keratins
    Ha1 KRTHA1 Ka25 K31 KRT31
    Ha2 KRTHA2 Ka26 K32 KRT32
    Ha3-I KRTHA3A Ka27 K33a KRT33A
    Ha3-II KRTHA3B Ka28 K33b KRT33B
    Ha4 KRTHA4 Ka29 K34 KRT34
    Ha5 KRTHA5 Ka30 K35 KRT35
    Ha6 KRTHA6 Ka31 K36 KRT36
    Ha7 KRTHA7 Ka32 K37 KRT37
    Ha8 KRTHA8 Ka33 K38 KRT38
Ka35 K39 KRT39
Ka36 K40 KRT40
Nonhuman hair/
epithelial keratins
φhHaA b,
Ka34P a man		 K41 chimp, gorilla KRT41 e chimp, gorilla
KRT41P man
    K17n mouse, ratf no designation Ka22 mouse, rat K42 mouse, rat KRT42 mouse, rat
KRT42P man
Human keratin pseudogenes
φhHaB b KRT221P
φKRTI b, Ka21P a KRT222P
φKRTJ b, Ka37P a KRT223P
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Human hair keratins

For the 11 human type I hair keratins (Table I), positions 29 and 30 were skipped and the keratins were numbered from 31–40 (Table II) to achieve a last digit matching between the current system (Table III, column 1) and the numbering system proposed herein (Table III, column 4; i.e., Ha1 → K31, etc). Note that K33a and K33b (the former Ha3-I and -II) are isoforms.

Nonhuman epithelial and hair keratins

We projected that 30 positions, 41–70 (Table II), i.e., considerably more than those comprising the human type I epithelial keratins, should be sufficient to cover this category of keratins. Pending their characterization at the gene/protein and tissue expression level, any new members of this type shall be added chronologically, independent of their nature as epithelial or hair keratins. Presently, there are only two keratins that fulfill these criteria (Table III). K41 represents a hair keratin that is differentially expressed in chimpanzee and gorilla hairs, whereas the human orthologue is a pseudogene (Winter et al., 2001). Similarly, K42 is the new designation for the recently described mouse and rat epithelial keratin K17n that is expressed mainly in nail tissue (Tong and Coulombe, 2004). The orthologous gene in humans is also a pseudogene (Troyanovsky et al.1992; Hesse et al., 2004; Rogers et al., 2004; Tong and Coulombe, 2004). Another candidate for this group is the keratin currently called Ka11, which is a rat keratin whose gene is nonfunctional in mice and absent from the human genome (Hesse et al., 2004).

New nomenclature for type II keratins Human epithelial keratins

Compared with the classical type I epithelial keratins, significantly more adjustments had to be made within the family of type II epithelial keratins K1–K8 (Table IV). The numbering of additional type II epithelial keratins begins with K71, after the nonhuman mammalian type I keratins (Table II). Thus, K71–K74 were assigned to the four type II inner root sheath keratins K6irs1–4 (Langbein et al., 2003; Table IV).

Table IV.

Type II keratins

Current protein
designation		 Current gene
designation		 Protein designation according to
Hesse et al., 2004 a 		New protein
designation		 New gene
designation
Human epithelial keratin
    K1 KRT1 Kb1 K1 KRT1
    K2e KRT2A Kb2 K2 KRT2
    K3 KRT3 Kb3 K3 KRT3
    K4 KRT4 Kb4 K4 KRT4
    K5 KRT5 Kb5 K5 KRT5
    K6a KRT6A Kb6 K6a KRT6A
    K6b KRT6B Kb10 K6b KRT6B
    K6e/h,a b no designation Kb12 K6cc KRT6C
    K7 KRT7 Kb7 K7 KRT7
    K8 KRT8 Kb8 K8 KRT8
    K6irs1 no designation Kb34 K71 KRT71
    K6irs2 no designation Kb35 K72 KRT72
    K6irs3 no designation Kb36 K73 KRT73
    K6irs4 no designation Kb37 K74 KRT74
    K6hf no designation Kb18 K75 KRT75
    K2p KRT2B Kb9 K76 KRT76
    K1bd no designation Kb39 K77 KRT77
    K5bd no designation Kb40 K78 KRT78
    K6ld no designation Kb38 K79 KRT79
    Kb20a b no designation Kb20 K80 KRT80
Human hair keratins
    Hb1, K2.9e KRTHB1 Kb21 K81 KRT81
    Hb2 KRTHB2 Kb22 K82 KRT82
    Hb3, K2.10e KRTHB3 Kb23 K83 KRT83
    Hb4 KRTHB4 Kb24 K84 KRT84
    Hb5, K2.12e KRTHB5 Kb25 K85 KRT85
    Hb6, K2.11e KRTHB6 Kb26 K86 KRT86
Nonhuman epithelial/
hair keratins
Human keratin pseudogenes
φhHbDb, Kb31Pa KRT121P
φhHbC b, Kb30P a KRT122P
φhHbB b, Kb29P a KRT123P
φhHbA b, Kb28P a KRT124P
φKRTH b KRT125P
φKRTG b, Kb19P a KRT126P
φKRTF b KRT127P
φKRTE b KRT128P
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c

Not identical with the polymorphic variant described previously by Takahashi et al.,1995; see Rogers et al., 2005 for further information;

The number of distinct variants of the K6 gene has been a matter for some discussion, but sequencing of the human genome has revealed that there are, in fact, only three K6 variants, each encoded by their own gene (Rogers et al., 2005). These are now designated K6a (KRT6A), K6b (KRT6B), and K6c (KRT6C). Because of its lack of conformity to the rules of the HGNC, the hair follicle–specific keratin K6hf (Winter et al., 1998; Wang et al., 2003) has been repositioned after the last inner root sheath keratin K74 and so renamed K75 (Table IV). For similar reasons of identity and nomenclature conformity, the epidermal keratin K2e has been redesignated K2, and the palatal keratin K2p (Collin et al., 1992a,b) has been renamed K76 (Table IV, column 4).

Although the completion of sequencing and analysis of the human type I keratin gene domain did not reveal any new keratin genes, that of the type II keratin gene domain led to the detection of four hitherto unknown genes whose encoded proteins had previously been designated K1b, K5b, K6l, and Kb20 (Hesse et al., 2001, 2004; Rogers et al. 2005; Table IV, column 1). Although there is only limited expression data available for K5b, K6l, and Kb20 (Rogers et al., 2005), keratin K1b has recently been demonstrated to be specifically expressed in eccrine sweat glands (Langbein et al., 2005). In the new nomenclature, these keratins are designated K77–K80 (Table IV, column 4). Collectively, K1–K8 and K71–K80 cover the twenty human type II epithelial keratins (Tables I and II).

Human hair keratins

Somewhat by design, the direct continuation of the numbering of the six human hair keratins (Table I), i.e., K81–K86, led to last digit matching between the old (Table IV, column 1) and the new nomenclature (Table IV, column 4), so that this kind of “aide-mémoire” exists for both types of human hair keratins.

Nonhuman epithelial/hair keratins

Unlike the situation for type I keratins, there are currently no type II keratins in this category. According to a recent study, putative mouse and rat candidate genes might be located in a region syntenic to the KRT6B, KRT6C, and KRT6A subcluster in the human genome (Hesse et al., 2004). The numbering allocated to such potential keratins ranges from 87 to 120 (Table II), thus, covering approximately the same range as that assigned to their type I counterparts.

New nomenclature for human type I and II pseudogene

Human keratin pseudogenes of both types were also included in the new nomenclature system, to give all-inclusive schemes of the type I and II keratin gene chromosomal domains, as shown in Fig. 1. Whereas the slots reserved for type II pseudogenes extend from 121–220, type I pseudogenes have an open system starting with 221 (Table II), as this is the last category to be named.

Figure 1.

Figure 1.

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Human keratin gene domains. (A) Type I. (B) Type II. Red, epithelial keratin genes; black, hair follicle-specific epithelial keratin genes; blue, hair keratin genes; green, pseudogenes.1 KRT18 is a type I gene.

Presently, there are eight keratin pseudogenes designated KRT121PKRT128P located within the type II keratin gene domain on chromosome 12q13.13 (Table IV, column 5). Of these, KRT121PKRT124P are hair keratin pseudogenes and KRT125PKRT128P are epithelial keratin pseudogenes (Fig. 1). Should some of these pseudogenes have active counterparts in other species, the encoded keratins will retain the numbering of the respective pseudogene without the suffix “P,” and, depending on their type, will be included in the respective category of nonhuman epithelial/hair keratins. The positions above 128 can be used to include keratin pseudogenes identified in other mammals.

The type I keratin gene domain contains two hair keratin and three epithelial keratin pseudogenes (Table III and Fig. 1). Two of them, the hair keratin pseudogene KRT41P and the epithelial keratin pseudogene KRT42P, possess active gene counterparts in other species and have already been named accordingly. The remaining three genes were designated KRT221PKRT223P (Table III, column 5).

It should be emphasized that in addition to the aforementioned type I and II keratin pseudogenes in the keratin gene domains on chromosomes 17 and 121, there are at least 61 processed pseudogenes for the type II keratin K8 and 77 for the type I keratin K18, which are dispersed throughout the human genome. Moreover, there are five processed pseudogenes for the type I keratin K19, which are single pseudogenes located on chromosomes 4, 6, and 10, with two pseudogenes located on chromosome 12. None of these contains an intact reading frame. Furthermore, the terminal segment on the human type I keratin gene domain spanning genes KRT14, KRT16, KRT17, and KRT42P (Fig. 1) is inserted four times into different regions of chromosome 17. This gives rise to three unprocessed pseudogenes for K14 and K16, and four for K17, as well as four KRT42P pseudogenes, which are all assumed to be nonfunctional (Hesse et al., 2001, 2004). The decision as to how these pseudogenes will be included into the respective lists of type I and II keratin pseudogenes will be left to the HGNC.

Concluding remarks

This modified and unifying nomenclature for mammalian keratins preserves the widely used and broadly referenced Moll designation system for the classical human epithelial keratins K1–K8 and K9–K24. The few changes that have been introduced reflect constraints to restrict the protein designation type K#$ (# = a number; $ = a letter) to true keratin isoforms. Accordingly, the new nomenclature will have no significant impact on current textbooks and commercial catalogs. Major changes are nearly all restricted to recently identified epithelial keratins. However, laboratories working on hair keratins will have to, under the new system, part with the 20-yr-old designations HaX and HbY and adopt new nomenclature. An effort has therefore been made to preserve the last digit between the old and the new designations, which is hoped will help researchers to adapt the new names. Although the new nomenclature assembles the human type I keratins into an almost uninterrupted series by preserving the original Moll nomenclature where possible, there is an unavoidable gap in the numbering of human type II keratins. Sufficient space has been left in the system for keratins occurring in other mammalian species, as well as for keratin pseudogenes. Moreover, we suggest that the term “keratin” rather than “cytokeratin” be used and that mammalian orthologues of human keratins be given the same naming system. As the revised nomenclature should facilitate communication and understanding within the community interested in keratins and their diseases, we advocate that this new system be used in all future studies.

Acknowledgments

The members of the Keratin nomenclature Committee are grateful to the following colleagues for their positive comments on the new keratin nomenclature: Bob Goldman, Kathy Green, Werner Franke, Elaine Fuchs, Rudolf Leube, Jürgen Markl, Irwin McLean, Roland Moll, Bob Oshima, Jim Rheinwald, George Rogers, Dennis Roop, and Klaus Weber.

Abbreviation used in this paper: HGNC, Human Genome Nomenclature Committee.

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