Conserved mechanism of dorsoventral axis determination in equal-cleaving spiralians

Many members of the spiralian phyla (i.e., annelids, echiurans, vestimentiferans, molluscs, sipunculids, nemerteans, polyclad turbellarians, gnathostomulids, mesozoans) exhibit early, equal cleavage divisions. In the case of the equal-cleaving molluscs, animal-vegetal inductive interactions between the derivatives of the first quartet micromeres and the vegetal macromeres specify which macromere becomes the 3D cell during the interval between fifth and sixth cleavage. The 3D macromere serves as a dorsal organizer and gives rise to the 4d mesentoblast. Even though it has been argued that this situation represents the ancestral condition among the Spiralia, these inductive events have only been documented in equal-cleaving molluscs. Embryos of the nemertean Cerebratulus lacteus also undergo equal, spiral cleavage, and the fate map of these embryos is similar to that of other spiralians. The role of animal first quartet micromeres in the establishment of the dorsal (D) cell quadrant was examined in C. lacteus by removing specific combinations of micromeres at the eight-cell stage. To follow the development of various cell quadrants, one quadrant was labeled with DiI at the four-cell stage, and specific first quartet micromeres were removed from discrete positions relative to the location of the labeled quadrant. The results indicate that the first quartet is required for normal development, as removal of all four micromeres prevented dorsoventral axis formation. In most cases, when either one or two adjacent first quartet micromeres were removed from one side of the embryo, the cell quadrant on the opposite side, with its macromere centered under the greatest number of the remaining animal micromeres, ultimately became the D quadrant. Twins containing duplicated dorsoventral axes were generated by removal of two opposing first quartet micromeres. Thus, any cell quadrant can become the D quadrant, and the dorsoventral axis is established after the eight-cell stage. While it is not yet clear exactly when key inductive interactions take place that establish the D quadrant in C. lacteus, contacts between the progeny of animal micromeres and vegetal macromeres are established during the interval between the fifth and sixth round of cleavage divisions (i.e., 32- to 64-cell stages). These findings argue that this mechanism of cell and axis determination has been conserved among equal-cleaving spiralians.     

What cell lineages tell us about the evolution of spiralia remains to be seen

Abstract.— Cell-lineage trees may contain information about spiralian phylogeny, as proposed by Guralnick and Lind-berg (2001). Here we discuss this possibility further and conclude that the cell-division pattern must be known in greater detail and the coding methods refined before a possible phylogenetic signal can be identified.     

The protease core of the muscle-specific calpain,p94, undergoes Ca2+-dependent intramolecular autolysis

Limb girdle muscular dystrophy type 2A is linked to a skeletal muscle-specific calpain isoform known as p94. Isolation of the intact 94-kDa enzyme has been difficult to achieve due to its rapid autolysis, and uncertainty has arisen over its Ca2+-dependence for activity. We have expressed a C-terminally truncated form of the enzyme that comprises the protease core (domains I and II) along with its insertion sequence, IS1, and N-terminal leader sequence, NS. This 47-kDa p94I-II mini-calpain was stable during purification. In the presence of Ca2+, p94I-II cleaved itself within the NS and IS1 sequences. Mapping of the autolysis sites showed that NS and IS1 have the potential to be removed without damage to the protease core. Ca2+-dependent autolysis must be an intramolecular event because the inactive p94I-II C129S mutant was not cleaved by incubation with wild-type p94I-II. In addition, the rate of autolysis of p94I-II was independent of the concentration of the enzyme.     

Sperm entry position provides a surface marker for the first cleavage plane of the mouse zygote

The sperm entry position (SEP) of the mouse egg, labelled by placing a bead at the fertilisation cone, tends to be associated with the first cleavage plane (Piotrowska and Zernicka-Goetz: Nature 409:517-521, 2001). Nevertheless, in up to one-fourth of embryos the cleavage furrow did not pass close to the bead, and following the division the bead marked the cleavage plane in only 60% of cases. This raised the question of whether such variability arose from the labelling itself or had a biological basis. The zona pellucida was not responsible for this effect because similar results were obtained in its presence or absence. However, this variability could be attributable to the large size of the fertilisation cone relative to the SEP. Therefore, we have developed a means of fluorescently labelling sperm that can record the exact site of its penetration when the label transfers to the egg surface. This approach indicates that the SEP marks the first cleavage in the great majority (88%) of embryos. In conclusion, direct sperm labelling shows precisely the correlation between the SEP and the first cleavage, although there is natural variability in this process.     

Statistical and Frequency-Amplitude Characteristics of Ultraweak Emissions of the Loach Eggs and Embryos under the Normal Conditions and during Their Optic Interactions. 1. Characteristics of Ultraweak Emission in Normal Development and the Optic Role of Egg Envelopes

Ultraweak emissions of groups comprising several dozens of unfertilized and fertilized loach eggs, embryos, larvae, and their egg envelopes were measured on a photomultiplier tube. The envelopes absorbed the light from external sources but readily gave it back in the absence of embryos. We carried out statistical and frequency-amplitude analyses of ultraweak emissions and studied the autocorrelation structure of their frequency spectra. The frequencies of signals with different intensity underwent regular changes during development. Cascades of short-term (1 ms) flashes timed (during cleavage) to furrowing were a characteristic element of ultraweak emission. The Fourier spectra of developing embryos had pronounced frequency-amplitude peaks and higher, than in unfertilized eggs and inanimate samples, mutual correlation during successive time intervals. Stage-specific translational symmetry of the frequency spectra of ultraweak emissions was demonstrated, which suggests the presence in groups of embryos of a coordinated system of harmonic oscillators. The latter underwent regular changes during development. The measurement of ultraweak emissions represents a unique non-invasive method of analysis of these oscillators.     

The mif gene is transcriptionally regulated by glucose in insulin-secreting cells

We have established that focal adhesion kinase (FAK)-transfected HL-60 (HL-60/FAK) cells were highly resistant to hydrogen peroxide and etoposide-induced apoptosis compared to vector-transfected cells. Mutagenesis study revealed that Y397 is required for anti-apoptotic activity in HL-60/FAK, since Y397F-mutated FAK (397FAK) lost anti-apoptotic function. Assuming that 397FAK functions as a dominant negative FAK, we introduced 397FAK cDNA into a human glioma cell line, T98G, using an adenoviral vector. We found that 397FAK induced marked apoptosis with significant FAK degradation. As PI3-kinase-Akt survival pathway was constitutively activated in T98G cells, we hypothesized that this pathway was shut off by 397FAK gene transfection. As expected, activation of PI3-kinase-Akt survival pathway was decreased by the 397FAK gene transfection. 397FAK activated mainly caspase-6 which induced degradation of transfected FAK as well as endogenous FAK. These results indicated that 397FAK induces apoptosis in T98G cells, by interrupting signals of FAK leading to the survival pathway in T98G glioma cells.     

Apparatus and mechanism of photosynthetic oxygen evolution: a personal perspective*

This historical minireview describes basic lines of progress in our understanding of the functional pattern of photosynthetic water oxidation and the structure of the Photosystem II core complex. After a short introduction into the state of the art about 35 years ago, results are reviewed that led to identification of the essential cofactors of this process and the kinetics of their reactions. Special emphasis is paid on the flash induced oxygen measurements performed by Pierre Joliot (in Paris, France) and Bessel Kok (Baltimore, MD) and their coworkers that led to the scheme, known as the Kok-cycle. These findings not only unraveled the reaction pattern of oxidation steps leading from water to molecular oxygen but also provided the essential fingerprint as prerequisite for studying individual redox reactions. Starting with the S. Singer and G. Nicolson model of membrane organization, attempts were made to gain information on the structure of the Photsystem II complex that eventually led to the current stage of knowledge based on the recently published X-ray crystal structure of 3.8 A resolution in Berlin (Germany).With respect to the mechanism of water oxidation, the impact of Gerald T. Babcock's hydrogen abstractor model and all the considerations of electron/proton transfer coupling are outlined. According to my own model cosiderations, the protein matrix is not only a 'cofactor holder' but actively participates by fine tuning via hydrogen bond networks, playing most likely an essential role in water substrate coordination and in oxygen-oxygen bond formation as the key step of the overall process.     

Evidence of cytochrome P450-catalyzed cleavage of the ether bond of phenoxybutyrate herbicides in Rhodococcus erythropolis K2-3

Bacterial strain Rhodococcus erythropolis K2-3 can cleave theether bond of the phenoxybutyrate herbicides, i.e., 4-(2,4-dichlorophenoxy)butyrate(2,4-DB) and 4-(4-chloro-2-methylphenoxy)butyrate (MCPB), by anenzyme system that is constitutively expressed. The enzyme(s) involved were investigated in this study. The rate ofdisappearance of 2,4-DB determined in a whole cell assay amounted to0.6 mmol/h ¶ g_{dry mass}.Carbon monoxide difference spectra of dithionite-reduced wholecells and crude cell extracts suggested that strain K2-3 contains a soluble cytochrome P450(P450), named P450_PB-1. The addition of various phenoxybutyrate substrates to crude cell extracts resulted in typical difference spectra following the type I pattern ofsubstrate binding with P450. The rate of 2,4-DB cleavage was reduced by inhibitors of P450: 5 mM metyrapone and carbon monoxide at a CO/O₂ ratio of 10 reduced the activity by about 20%, and 70%, respectively. The ether cleaving activity completely disappearedafter disruption of the cells and could not be detected in crude extracts. To elucidate theenzymatic basis of this reaction, P450 was partially purified. With the resulting enzyme preparation,2,4-DB cleavage activity was re-established, becoming measurable after the addition of eitherphenazine methosulfate or ferredoxin and ferredoxin/NADP oxidoreductase from spinach. We detected no activities attributable to -ketoglutarate-dependent dioxygenase orNAD(P)H-dependent monooxygenase. These results collectively indicatethat cleavage of the ether bond of phenoxybutyrate herbicides is catalyzed by P450-mediated activityin this strain. One of the products derived from this reaction is dichlorophenol, and comparativechromatographic analyses suggest that the other product is a C4-carbonicacid, most likely succinic semialdehyde/succinate.