A variant of the Southern German clone of methicillin-resistant Staphylococcus aureus is predominant in Croatia.

The aim of the present study was to investigate the antibiotic susceptibility patterns and molecular epidemiology of clinical methicillin-resistant Staphylococcus aureus (MRSA) isolates recovered in 24 hospitals in 20 cities in Croatia from October to December 2004. A total of 1815 consecutive S. aureus isolates were recovered, 248 of which were MRSA. The MRSA isolates were analysed using spa typing, multilocus sequence typing and SCCmec typing. Furthermore, the presence of Panton-Valentine leukocidin (PVL) genes was determined as a genetic marker for community-associated MRSA. The MRSA prevalence was 14%. Ninety-six per cent of the MRSA isolates were resistant to ciprofloxacin, 95% to clindamycin and azithromycin, 94% to gentamicin, and 93% to erythromycin. The majority of the MRSA isolates (78%) was associated with the ST111-MRSA-I clone. In addition, various other endemic MRSA clones were observed, such as the ST247-MRSA-I (4%), the ST45-MRSA-IV (2%), the ST5-MRSA-I (2%), the ST239-MRSA-III (2%), the ST5-MRSA-II (1%), the ST8-MRSA-IV (1%) and the ST5-MRSA-IV (<1%) clones. Furthermore, we observed one PVL-negative ST80-MRSA-IV isolate. Four PVL-positive MRSA isolates were found, associated with ST8-MRSA-IV, ST80-MRSA-IV and ST80-MRSA-I. The ST111-MRSA-I clone was predominant in Croatia. Future surveillance studies of MRSA are important to elucidate whether changes in the clonal distribution of MRSA will occur, and if the minor endemic MRSA clones observed in the present study will replace the ST111-MRSA-I clone on a large scale.

Bruton tyrosine kinase-like protein, BtkSD, is present in the marine sponge Suberites domuncula.

Sponges, the simplest and most ancient phylum of Metazoa, encode in their genome complex and highly sophisticated proteins that evolved together with multicellularity and are found only in metazoan animals. We report here the finding of a Bruton tyrosine kinase (BTK)-like protein in the marine sponge Suberites domuncula (Demospongiae). The nucleotide sequence of one sponge cDNA predicts a 700-aa-long protein, which contains all of the characteristic domains for the Tec family of protein tyrosine kinases (PTKs). The highest homology (38% identity, 55% overall similarity) was found with human BTK and TEC PTKs. Sponge PTK was therefore named BtkSD. Human BTK is involved in the maturation of B cells and mutations in the BTK gene cause X-linked agammaglobulinemia. Kinases from the Tec family are not present in Caenorhabditis elegans and, until now, they were found only in insects and higher animal taxa. Our finding implies that the BTK/TEC genes are of a very ancient origin.

Characterization and phylogenetic analysis of a cDNA encoding the Fes/FER related, non-receptor protein-tyrosine kinase in the marine sponge sycon raphanus.

In search of ancient versions of phylogenetically conserved genes/proteins, which are typical for multicellular animals, we have decided to analyse marine sponges (Porifera), the most ancient and most primitive metazoan organisms. We report here the complete nucleotide sequence of Sycon raphanus cDNA coding for a 879 aa long protein, which displays high overall similarity in primary structure and organization of domains with non-receptor tyrosine kinases (TKs) from the Fes/FER family. The encoded protein, which we named Fes/FER_SR, has a highly conserved, 260 aa long tyrosine kinase domain at the C-terminus. Amino-terminal to the catalytic domain is an 85 aa long SH2 domain. The N-terminus is over 500 aa long and displays homology only with N-terminal domains of protein-tyrosine kinases (PTKs) from the Fes/FER family. Mammalian Fes/FER proteins show around 58% overall homology with Fes/FER_SR (identity and similarity) and lower homology was found with Drosophila melanogaster Fps (FER) protein (49%). Homologies in TK, SH2 and N-terminal domains are on average 78%, 65% and 49%, respectively. Fes/FER_SR shows next to best homology with the Abl family of non-receptor PTKs, while Src-related PTKs from the fresh-water sponge Spongilla lacustris are related only distantly to Fes/FER_SR. Phylogenetic analysis shows that the S. raphanus TK is indeed the most ancient known member of the Fes/FER family of non-receptor PTKs. The role of these PTKs in signal transduction in higher animals is still enigmatic; they are present in the nucleus as well as in the cytoplasm and FER is found in all cell types examined. The function of Fes/FER_SR in sponge, the most primitive multicellular animal which lacks specialized organ systems, remains to be elucidated.

Molecular evolution of the metazoan protein kinase C multigene family.

Protein kinases C (PKCs) comprise closely related Ser/Thr kinases, ubiquitously present in animal tissues; they respond to second messengers, e.g., Ca2+ and/or diacylglycerol, to express their activities. Two PKCs have been sequenced from Geodia cydonium, a member of the lowest multicellular animals, the sponges (Porifera). One sponge G. cydonium PKC, GCPKC1, belongs to the "novel" (Ca2+-independent) PKC (nPKC) subfamily while the second one, GCPKC2, has the hallmarks of the "conventional" (Ca2+-dependent) PKC (cPKC) subfamily. The alignment of the Ser/Thr catalytic kinase domains, of the predicted aa sequences for these cDNAs with respective segments from previously reported sequences, revealed highest homology to PKCs from animals but also distant relationships to Ser/Thr kinases from protozoa, plants, and bacteria. However, a comparison of the complete structures of the sponge PKCs, which are-already-identical to those of nPKCs and cPKCs from higher metazoa, with the structures of protozoan, plant, and bacterial Ser/Thr kinases indicates that the metazoan PKCs have to be distinguished from the nonmetazoan enzymes. These data indicate that metazoan PKCs have a universal common ancestor which they share with the nonmetazoan Ser/Thr kinases with respect to the kinase domain, but they differ from them in overall structural composition.

Molecular evidence for the presence of a developmental gene in the lowest animals: identification of a homeobox-like gene in the marine sponge Geodia cydonium.

During the development of higher animals, morphogenetic programs are switched on which are frequently controlled by homeotic genes. Until now these genes have not been identified in the lowest animals, the marine sponges. Since sponges show (i) an antero-posterior and/or dorso-ventral axis during embryogenesis and (ii) a complex differentiation pattern during spicula formation, we hypothesized that in sponges homeotic genes--if present--are also involved in the control of these processes. Therefore, we searched for homeobox or homeobox-like sequences in the marine sponge Geodia cydonium. Here we describe a homeobox-like sequence from these animals; it was isolated from a cDNA library of an adult specimen. The deduced amino acid sequence of the complete homeodomain shares over 70% similarity with other homeodomain sequences, including those from hydra, insects and vertebrates. These data indicate that the sponge homeodomain-like sequence is similar with respect to structure to those of other animals and may suggest that the sponge homeodomain-like sequence(s) might function during developmental processes and/or during spiculogenesis in a similar manner to that known for higher animals.