Rapid preparation of Fusarium DNA from cereals for diagnostic PCR u sing sonification and an extraction kit

Several PCR methods have recently been developed for Fusarium analysis in pure cultures. To use these new techniques in mycological studies and in industrial quality control, a protocol was set up for the rapid preparation of fungal DNA from cereals. An ultrasonification probe (sonotrode) and a lysis buffer were used for mechanical lysis of mycelia from infected grains. Following ultrasonification, DNA was isolated using a commercially available kit. DNA preparation was completed within 5 min per sample. The method resulted in DNA of sufficient quality and quantity for diagnostic PCR. Group- and species-specific primers were used to detect DNA of Fusarium graminearum and F. culmorum in species-specific assays as well as trichothecene-producing Fusarium spp. in a group-specific system. A minimum of one F. graminearum -infected grain added to an uninfected 40 g wheat sample was detectable with a species-specific PCR. The PCR signals produced with primers specific for the tri5 gene of trichothecene-producing Fusarium spp. and with primers for the detection of F. graminearum (gaoA) were in accordance with corresponding concentrations of deoxynivalenol (DON) found in samples by HPLC analysis. The speed of the protocol developed may promote the use of PCR in routine applications in an agro-industrial context.     

Buffalo (Bubalus bubalis) Pre-antral Follicle Population and Ultrastructural Characterization of Antral Follicle Oocyte

The main objectives of the present study were to determine the ultrastructural modifications occurring in the oocyte during late folliculogenesis and to estimate pre-antral follicle population in buffalo. Half the collected ovaries were fixed and prepared for optic microscopy; the antral follicles from the other ovaries were measured and individually punctured. The cumulus–oocyte complexes (COCs) were processed for transmission electron microscopy. The number of pre-antral follicles in buffalo ovaries was estimated at 19 819 structures. Cumulus–oocyte complexes derived from 1-mm antral follicle had an eccentrical nucleus and compact corona radiata , ooplasm vilosities were fully embedded in zona pellucida (ZP) and a well-defined junction could be observed. Mitochondria were predominantly round and well distributed in ooplasm, as were small lipid vacuoles. In COCs derived from 2-mm antral follicles, the initial formation of perivitelline space was observed. The nucleus was peripherally located and the number of pleomorphic mitochondria increased. Cortical granules were clustered at oocyte periphery and lipid vacuoles increased in number and size. In COCs derived from 6-mm antral follicles, the organelles were located mainly in the perinuclear region. Golgi complexes and smooth endoplasmic reticulum (SER) were more developed. Mitochondria migrated to the cortical region and lipid vacuoles migrated to the medullar region. In COCs derived from 10-mm antral follicles, the lipid vacuoles coalesced and occupied the medullar region of the oocyte, together with a well-developed SER. Mitochondria were pleomorphic and located at the oocyte periphery. In conclusion, the morphological differences described in this paper could be responsible for some functional differences observed in in vitro embryo production and follicular dynamics for buffalo, when compared with cattle.