Loss of the PGE1 requirement for MDCK cell growth associated with a defect in cyclic AMP phosphodiesterase

Prostaglandin E₁(PGE₁), one of the components in the hormone-supplemented, serum-free medium for Madin Darby Canine Kidney (MDCK) cells (Medium K-1), is required for both long-term growth and for dome formation. Variant cells have been isolated from MDCK populations, which lack the PGE₁, requirement for long-term growth in Medium K-1. These variants will be useful in identifying the molecular events initiated by PGE₁ which are necessary for the growth response to be observed. The growth and functional properties of five independently isolated PGE₁ independent clones have been examined. Normal MDCK cells grew at an equivalent rate in Medium K-1 and in serum-supplemented medium; the growth rate was lower in Medium K-1 lacking PGE₁. In contrast, PGE₁ independent clone 1 grew at an equivalent rate in Medium K-1 minus PGE₁, and in serum-supplemented medium. When PGE₁ was added to K-1 minus PGE₁, less growth of PGE₁ independent clone 1 was observed. A similar observation was made with one other PGE₁ independent clone which was studied. A hormone deletion study indicated that PGE₁ independent clone 1 still retained growth responses to the other four supplements in Medium K-1 (insulin, transferrin, T₃, and hydrocortisone). The molecular alterations associated with loss of the PGE₁ requirement for long-term growth were examined. At confluency, all of the PGE₁ independent clones studied had higher intracellular cyclic AMP levels following PGE₁ treatment, as compared with normal MDCK cells. The increased cyclic AMP levels in the variant cells could result from a number of different types of defects, including reduced cyclic adenylic acid (cyclic AMP) efflux, an increased affinity of PGE₂ for the PGE₁ receptor, or a defect in cyclic AMP metabolism. However, in all of the variant clones studied a decreased rate of cyclic AMP degradation by cyclic AMP phosphodiesterase was observed. Thus, the increased cyclic AMP levels in the PGE₁ independent variants may result from alterations which affect cyclic AMP metabolism. The effect of PGE₁ on dome formation by the variant cells was also examined. The frequency of dome formation by PGE₁ independent clone 1 was enhanced in a dosage-dependent manner, like normal MDCK cells. This observation suggests that PGE₁ affects MDCK cell growth and dome formation by different mechanisms.     

P-type ATPases of eukaryotes and bacteria: Sequence analyses and construction of phylogenetic trees

The amino acid sequences of 47 P-type ATPases from several eukaryotic and bacterial kingdoms were divided into three structural segments based on individual hydropathy profiles. Each homologous segment was (1) multiply aligned and functionally evaluated, (2) statistically analyzed to determine the degrees of sequence similarity, and (3) used for the construction of parsimonious phylogenetic trees. The results show that all of the P-type ATPases analyzed comprise a single family with four major clusters correlating with their cation specificities and biological sources as follows: cluster 1: Ca²⁺-transporting ATPases; cluster 2: Na⁺- and gastric H⁺-ATPases; cluster 3: plasma membrane H⁺-translocating ATPases of plants, fungi, and lower eukaryotes; and cluster 4: all but one of the bacterial P-type ATPases (specific for K⁺, Cd²⁺, Cu²⁺ and an unknown cation). The one bacterial exception to this general pattern was the Mg²⁺-ATPase of Salmonella typhimurium, which clustered with the eukaryotic sequences. Although exceptions were noted, the similarities of the phylogenetic trees derived from the three segments analyzed led to the probability that the N-terminal segments 1 and the centrally localized segments 2 evolved from a single primordial ATPase which existed prior to the divergence of eukaryotes from prokaryotes. By contrast, the C-terminal segments 3 appear to be eukaryotic specific, are not found in similar form in any of the prokaryotic enzymes, and are not all demonstrably homologous among the eukaryotic enzymes. These C-terminal domains may therefore have either arisen after the divergence of eukaryotes from prokaryotes or exhibited more rapid sequence divergence than either segment 1 or 2, thus masking their common origin. The relative rates of evolutionary divergence for the three segments were determined to be segment 2 < segment 1 < segment 3. Correlative functional analyses of the most conserved regions of these ATPases, based on published site-specific mutagenesis data, provided preliminary evidence for their functional roles in the transport mechanism. Our studies define the structural and evolutionary relationships among the P-type ATPases. They should provide a guide for the design of future studies of structure-function relationships employing molecular genetic, biochemical, and biophysical techniques. Correspondence to: M.H. Saier, Jr.     

Computer-aided analyses of transport protein sequences: gleaning evidence concerning function, structure, biogenesis, and evolution.

Three-dimensional structures have been elucidated for very few integral membrane proteins. Computer methods can be used as guides for estimation of solute transport protein structure, function, biogenesis, and evolution. In this paper the application of currently available computer programs to over a dozen distinct families of transport proteins is reviewed. The reliability of sequence-based topological and localization analyses and the importance of sequence and residue conservation to structure and function are evaluated. Evidence concerning the nature and frequency of occurrence of domain shuffling, splicing, fusion, deletion, and duplication during evolution of specific transport protein families is also evaluated. Channel proteins are proposed to be functionally related to carriers. It is argued that energy coupling to transport was a late occurrence, superimposed on preexisting mechanisms of solute facilitation. It is shown that several transport protein families have evolved independently of each other, employing different routes, at different times in evolutionary history, to give topologically similar transmembrane protein complexes. The possible significance of this apparent topological convergence is discussed.     

Enzyme IIBcellobiose of the phosphoenol-pyruvate-dependent phosphotransferase system of Escherichia coli: backbone assignment and secondary structure determined by three-dimensional NMR spectroscopy.

The assignment of backbone resonances and the secondary structure determination of the Cys 10 Ser mutant of enzyme IIBcellobiose of the Escherichia coli cellobiose-specific phosphoenol-pyruvate-dependent phosphotransferase system are presented. The backbone resonances were assigned using 4 triple resonance experiments, the HNCA and HN(CO)CA experiments, correlating backbone 1H, 15N, and 13C alpha resonances, and the HN(CA)CO and HNCO experiments, correlating backbone 1H,15N and 13CO resonances. Heteronuclear 1H-NOE 1H-15N single quantum coherence (15N-NOESY-HSQC) spectroscopy and heteronuclear 1H total correlation 1H-15N single quantum coherence (15N-TOCSY-HSQC) spectroscopy were used to resolve ambiguities arising from overlapping 13C alpha and 13CO frequencies and to check the assignments from the triple resonance experiments. This procedure, together with a 3-dimensional 1H alpha-13C alpha-13CO experiment (COCAH), yielded the assignment for all observed backbone resonances. The secondary structure was determined using information both from the deviation of observed 1H alpha and 13C alpha chemical shifts from their random coil values and 1H-NOE information from the 15N-NOESY-HSQC. These data show that enzyme IIBcellobiose consists of a 4-stranded parallel beta-sheet and 5 alpha-helices. In the wild-type enzyme IIBcellobiose, the catalytic residue appears to be located at the end of a beta-strand.     

A major difference between the divergence patterns within the lines-1 families in mice and voles

L1 retroposons are represented in mice by subfamilies of interspersed sequences of varied abundance. Previous analyses have indicated that subfamilies are generated by duplicative transposition of a small number of members of the L1 family, the progeny of which then become a major component of the murine L1 population, and are not due to any active processes generating homology within preexisting groups of elements in a particular species. In mice, more than a third of the L1 elements belong to a clade that became active approximately 5 Mya and whose elements are > or = 95% identical. We have collected sequence information from 13 L1 elements isolated from two species of voles (Rodentia: Microtinae: Microtus and Arvicola) and have found that divergence within the vole L1 population is quite different from that in mice, in that there is no abundant subfamily of homologous elements. Individual L1 elements from voles are very divergent from one another and belong to a clade that began a period of elevated duplicative transposition approximately 13 Mya. Sequence analyses of portions of these divergent L1 elements (approximately 250 bp each) gave no evidence for concerted evolution having acted on the vole L1 elements since the split of the two vole lineages approximately 3.5 Mya; that is, the observed interspecific divergence (6.7%-24.7%) is not larger than the intraspecific divergence (7.9%-27.2%), and phylogenetic analyses showed no clustering into Arvicola and Microtus clades.      

Response regulators of bacterial signal transduction systems: Selective domain shuffling during evolution

Response regulators of bacterial sensory transduction systems generally consist of receiver module domains covalently linked to effector domains. The effector domains include DNA binding and/or catalytic units that are regulated by sensor kinase-catalyzed aspartyl phosphorylation within their receiver modules. Most receiver modules are associated with three distinct families of DNA binding domains, but some are associated with other types of DNA binding domains, with methylated chemotaxis protein (MCP) demethylases, or with sensor kinases. A few exist as independent entities which regulate their target systems by noncovalent interactions.In this study the molecular phylogenies of the receiver modules and effector domains of 49 fully sequenced response regulators and their homologues were determined. The three major, evolutionarily distinct, DNA binding domains found in response regulators were evaluated for their phylogenetic relatedness, and the phylogenetic trees obtained for these domains were compared with those for the receiver modules. Members of one family (family 1) of DNA binding domains are linked to large ATPase domains which usually function cooperatively in the activation of E. Coli ⁵⁴-dependent promoters or their equivalents in other bacteria. Members of a second family (family 2) always function in conjunction with the E. Coli ⁷⁰ or its equivalent in other bacteria. A third family of DNA binding domains (family 3) functions by an uncharacterized mechanism involving more than one a factor. These three domain families utilize distinct helix-turn-helix motifs for DNA binding.The phylogenetic tree of the receiver modules revealed three major and several minor clusters of these domains. The three major receiver module clusters (clusters 1, 2, and 3) generally function with the three major families of DNA binding domains (families 1, 2, and 3, respectively) to comprise three classes of response regulators (classes 1, 2, and 3), although several exceptions exist. The minor clusters of receiver modules were usually, but not always, associated with other types of effector domains. Finally, several receiver modules did not fit into a cluster. It was concluded that receiver modules usually diverged from common ancestral protein domains together with the corresponding effector domains, although domain shuffling, due to intragenic splicing and fusion, must have occurred during the evolution of some of these proteins.Multiple sequence alignments of the 49 receiver modules and their various types of effector domains, together with other homologous domains, allowed definition of regions of striking sequence similarity and degrees of conservation of specific residues. Sequence data were correlated with structure/function when such information was available. These studies should provide guides for extrapolation of results obtained with one response regulator to others as well as for the design of future structure/function analyses. Correspondence to: M.H. Saier, Jr.     

The NMR side-chain assignments and solution structure of enzyme IIBcellobiose of the phosphoenolpyruvate-dependent phosphotransferase system of Escherichia coli.

The assignment of the side-chain NMR resonances and the determination of the three-dimensional solution structure of the C10S mutant of enzyme IIBcellobiose (IIBcel) of the phosphoenolpyruvate-dependent phosphotransferase system of Escherichia coli are presented. The side-chain resonances were assigned nearly completely using a variety of mostly heteronuclear NMR experiments, including HCCH-TOCSY, HCCH-COSY, and COCCH-TOCSY experiments as well as CBCACOHA, CBCA(CO)NH, and HBHA(CBCA)(CO)NH experiments. In order to obtain the three-dimensional structure, NOE data were collected from 15N-NOESY-HSQC, 13C-HSQC-NOESY, and 2D NOE experiments. The distance restraints derived from these NOE data were used in distance geometry calculations followed by molecular dynamics and simulated annealing protocols. In an iterative procedure, additional NOE assignments were derived from the calculated structures and new structures were calculated. The final set of structures, calculated with approximately 2000 unambiguous and ambiguous distance restraints, has an rms deviation of 1.1 A on C alpha atoms. IIBcel consists of a four stranded parallel beta-sheet, in the order 2134. The sheet is flanked with two and three alpha-helices on either side. Residue 10, a cysteine in the wild-type enzyme, which is phosphorylated during the catalytic cycle, is located at the end of the first beta-strand. A loop that is proposed to be involved in the binding of the phosphoryl-group follows the cysteine. The loop appears to be disordered in the unphosphorylated state.     

Evolutionary relationships among the permease proteins of the bacterial phosphoenolpyruvate: Sugar phosphotransferase system. Construction of phylogenetic trees and possible relatedness to proteins of eukaryotic mitochondria

Summary The amino acid sequences of 15 sugar permeases of the bacterial phosphoenolpyruvatedependent phosphotransferase system (PTS) were divided into four homologous segments, and these segments were analyzed to give phylogenetic trees. The permease segments fell into four clusters: the lactose-cellobiose cluster, the fructose-mannitol cluster, the glucose-N-acetylglucosamine cluster, and the sucrose--glucoside cluster. Sequences of the glucitol and mannose permeases (clusters 5 and 6, respectively) were too dissimilar to establish homology with the other permeases, but short regions of statistically significant sequence similarities were noted. The functional and structural relationships of these permease segments are discussed.Some of the homologous PTS permeases were found to exhibit sufficient sequence similarity to subunits 4 and 5 of the eukaryotic mitochondrial NADH dehydrogenase complex to suggest homology. Moreover, subunits 4 and 5 of this complex appeared to be homologous to each other, suggesting that these PTS and mitochondrial proteins comprise a superfamily. The integral membrane subunits of the evolutionarily divergent mannose PTS permease, the P and M subunits, exhibited limited sequence similarity to subunit 6 of the mitochondrial F₁F₀-ATPase and subunit 5b of cytochrome oxidase, respectively. These results suggest that PTS sugar permeases and mitochondrial proton-translocating proteins may be related, although the possibility of convergent evolution cannot be ruled out.     

Membrane insertion of the mannitol permease of Escherichia coli occurs under conditions of impaired SecA function.

The membrane insertion of the mannitol permease (MtlA protein) of Escherichia coli, a polytopic cytoplasmic membrane protein possessing an uncleaved amphiphilic signal sequence, was studied using a cell-free protein synthesis system. The MtlA protein synthesized in the presence of inside-out cytoplasmic membrane vesicles was shown to insert into the membranes based on the following criteria: (a) co-sedimentation of the majority of the MtlA protein with the vesicles; (b) selective extraction of the membrane-associated MtlA by doxycholate but not by urea treatment; and (c) protease resistance of a defined MtlA fragment observed exclusively in the presence of membranes. Post-translational addition of membrane vesicles allowed membrane association of MtlA but did not allow efficient integration. In cell-free systems having reduced levels of the export factors SecA and SecB and exhibiting defective translocation of preOmpA and preLamB, insertion of the in vitro synthesized MtlA apparently occurred normally. In contrast, when membranes from the secY24ts mutant or trypsin-treated membranes were used, insertion of MtlA was reduced. In vivo experiments monitoring the permease activity of MtlA in the secA and secY mutants supported the conclusions of the in vitro results. Thus, the insertion of MtlA is essentially SecA- and SecB-independent but may be dependent on SecY and/or an as yet unidentified membrane protein. The requirements for the insertion of the mannitol permease are therefore clearly different from those for the translocation of most proteins having a cleavable hydrophobic signal sequence.