Accuracy of blood cytological screening techniques for the diagnosis of a possible hematopoietic neoplasm in the bivalve mollusc,Mya arenaria

The two in vivo bleeding techniques currently in use in our laboratory to diagnose a hematopoietic neoplasm in Mya arenaria are: (1) phase-contrast microscopy with fresh unstained hemocytes, and (2) bright-field microscopy with Giemsa-stained hemocytes. All in vivo diagnoses were checked by histopathological studies on tissues of the same mollusc. For both methods the correct diagnosis (true + or true ?) was made in 94 out of 100 clams examined. A gradation of tissue involvement was observed in the diseased clams and the accuracy of the in vivo diagnosis is related to the disease severity. There is a positive correlation between the degree of tissue involvement and the number of circulating neoplastic cells. For this reason the more extensive the neoplasm the better is the ability to diagnose the neoplasm by the in vivo bleeding techniques. Depending on the percentage of neoplastic cells present in the hemolymph, the neoplasm was graded from level 1 to 5, with 5 being the most severe. In general, at level 1, the accuracy of a single in vivo diagnosis varied from 66 to 71% and at level 2, the accuracy of diagnosis varied from 76 to 93%, while at all other levels the accuracy was 100%. The percentage of diseased clams detected by the in vivo bleeding technique was 89–91% and the percentage of nondiseased clams detected was 95%. These values can be further improved by combining the two tests and/or through multiple bleedings. Between the two types of in vivo tests, the Giemsa-stained hemocytes provided better precision of diagnosis than the fresh unstained cells, although the differences were slight.     

Photosystem I reaction center: past and future

Science has always been drawn to uncover fundamental life processes. Photosynthesis is one, if not the most fascinating, of them. Within it, the protein complexes that catalyze light-induced electron transport and photophosphorylation are enchanting creations of evolution. Plant Photosystem I (PS I) is not the largest protein complex in nature but it is the most elaborate in the number of prosthetic groups involved in its fabric. Thirty years ago, one of us (NN) developed a fascination for this complex and, despite the apparent neglect (lack of publications in the last few years), never let it go. Only a crystal structure at 2 A resolution will satiate our curiosity. In this minireview, we trace the past, and end the article with a comment on future prospects. For the present situation, see Parag Chitnis (2001).     

Changing concepts about the distribution of Photosystems I and II between grana-appressed and stroma-exposed thylakoid membranes

Thylakoid membranes of higher plants and some green algae, which house the light-harvesting and energy transducing functions of the chloroplast, are structurally unique. The concept of the photosynthetic unit of the 1930s (Robert Emerson, William Arnold and Hans Gaffron), needing one reaction center per hundreds of antenna molecules, was modified by the discovery of the Enhancement effect in oxygen evolution in two different wavelengths of light (Robert Emerson and his coworkers) in the late 1950s, followed by the 1960 Z scheme of Robin Hill and Fay Bendall. It was realized that two light reactions and two pigment systems were needed for oxygenic photosynthesis. Changing ideas about the distribution of Photosystem II (PS II) and PS I between the green-appressed and stroma-exposed thylakoid membrane domains, which led to the concept of lateral heterogeneity, are discussed. This revised version was published online in June 2006 with corrections to the Cover Date.     

Spatial and non-spatial discrimination reversal (SDR) learning in the guinea pig

Spatial and non-spatial serial discrimination reversal performance was investigated in guinea pigs over eleven reversals. Difference in learning ability between albino and pigmented strains was not evident on spatial or non-spatial SDR tasks. The guinea pigs' ability to learn rapidly successive spatial and non-spatial reversals with increasing proficiency corresponds well with previous published findings using other mammalian species. These studies also demonstrated behavioural research with the guinea pig to require extended periods of intensive experimental management.