Real-time PCR validation to estimate the number of rickettsias in the biological material under study.

Using the example of the clinical strain of R. sibirica «Bayevo 105/87», the possibility of quantitative determination of rickettsias in clinical samples from patients with Siberian tick-borne typhus by real-time polymerase chain reaction (PCR-RT) was evaluated. Cultivation was carried out in the yolk sacs of developing chicken embryos, from which a piece of the yolk sac or chorion was taken. A total of 125 samples were examined. A set of reagents "RealBest DNA Rickettsia species (kit1)" was used for PCR-RT. The obtained values of the threshold amplification cycle (Ct) were compared with the results of microscopy of smear preparations stained by the Zdrodovsky method, the values of which were divided into ranks: the I rank - single rickettsias in individual fields of vision, the II rank - single rickettsias in each field of vision, the III rank - from 10 to 25 rickettsias in each field of vision, the IV rank - from 25 to 50 rickettsias in each field of view. The median Ct value for rank I was 17.6 (16.37; 18.58), for the II - 16.0 (15.0; 16.41), for the III - 15.0 (14.0; 15.1) and for the IV - 15.0 (13.7; 14.64). A significant average correlation was established between the number of rickettsias in the preparation under microscopy and the value of the threshold cycle in PCR RT (r=-0, 4849542; p=9.968e-09). When determining the correlation between the pathomorphological characteristic and the value of the threshold cycle, its absence was established. The detection of rickettsias in the blood vessels of the chorion of developing chicken embryos was of interest. In 10 samples, the yolk sac and chorion were taken for the study, and in parallel they were examined by PCR-RT. The use of modern, more sensitive molecular biological methods allows for quantitative analysis of DNA in the chorion, while preserving the volumes of the most valuable material - the yolk sac.

[1]  D. V. Trankvilevsky,et al.  Epidemiological Situation on Tick-Borne Spotted Fever Group Rickettsioses in the Russian Federation in 2012–2021, Prognosis for 2022–2026 , 2022, Problems of Particularly Dangerous Infections.

[2]  A. Kubyshkin,et al.  Prevalence of causative agents of transmissive tick-borned ricketsious in the Crimean peninsula. , 2022, Russian Clinical Laboratory Diagnostics.

[3]  D. V. Trankvilevsky,et al.  Features of the Epidemiological Situation on Tick-Borne Rickettsioses in the Russian Federation in 2010–2020 and Prognosis for 2021 , 2021, Problems of Particularly Dangerous Infections.

[4]  A. Shvalov,et al.  The role of Rhipicephalus sanguineus ticks parasitizing dogs in the spread of tick-borne rickettsial pathogens in the city of Sevastopol , 2020, New microbes and new infections.

[5]  P. Patel,et al.  Development of a pan-rickettsial molecular diagnostic test based on recombinase polymerase amplification assay. , 2018, Analytical biochemistry.

[6]  F. Segura,et al.  Shell-vial culture, coupled with real-time PCR, applied to Rickettsia conorii and Rickettsia massiliae-Bar29 detection, improving the diagnosis of the Mediterranean spotted fever. , 2016, Ticks and tick-borne diseases.

[7]  M. Eremeeva,et al.  Modern Approaches to Laboratory Diagnosis of Rickettsial Diseases , 2014 .

[8]  A. Azad,et al.  Laboratory Maintenance of Rickettsia rickettsii , 2008, Current protocols in microbiology.

[9]  G. Baranton,et al.  Guidelines for the diagnosis of tick-borne bacterial diseases in Europe. , 2004, Clinical microbiology and infection : the official publication of the European Society of Clinical Microbiology and Infectious Diseases.

[10]  A. Shvalov,et al.  TICK-BORNE RICKETTSIOSIS CASED BY RICKETTSIA HEILONGJIANGENSIS, AND ITS LABORATORY DIAGNOSTICS IN THE ALTAI REPUBLIC , 2020, Современные проблемы науки и образования (Modern Problems of Science and Education).

[11]  V. Dedkov,et al.  LABORATORY DIAGNOSTICS OF TISSUE INFECTIONS WITH NATURAL FOCUS (TICK-BORNE RICKETTSIOSIS, IXODIC TICK-BORNE BORRELIOSIS) , 2017 .