A faster and less costly alternative for RNA extraction of SARS-CoV-2 using proteinase k treatment followed by thermal shock.

One of the biggest challenges during the pandemic has been obtaining and maintaining critical material to conduct the increasing demand for molecular tests. Sometimes, the lack of suppliers and the global shortage of these reagents, a consequence of the high demand, make it difficult to detect and diagnose patients with suspected SARS-CoV-2 infection, negatively impacting the control of virus spread. Many alternatives have enabled the continuous processing of samples and have presented a decrease in time and cost. These measures thus allow broad testing of the population and should be ideal for controlling the disease. In this sense, we compared the SARS-CoV-2 molecular detection effectiveness by Real time RT-PCR using two different protocols for RNA extraction. The experiments were conducted in the National Institute of Health (INS) from Peru. We compared Ct values average (experimental triplicate) results from two different targets, a viral and internal control. All samples were extracted in parallel using a commercial kit and our alternative protocol-samples submitted to proteinase K treatment (3 µg/µL, 56°C for 10 minutes) followed by thermal shock (98°C for 5 minutes followed by 4°C for 2 minutes); the agreement between results was 100% in the samples tested. In addition, we compared the COVID-19 positivity between six epidemiological weeks: the initial two in that the Real time RT-PCR reactions were conducted using RNA extracted by commercial kit, followed by two other using RNA obtained by our kit-free method, and the last two using kit once again; they did not differ significantly. We concluded that our in-house method is an easy, fast, and cost-effective alternative method for extracting RNA and conducing molecular diagnosis of COVID-19.

[DESIGN AND EVALUATION OF A MULTIEPITOPIC PROTEIN AS A CANDIDATE FOR A CARRION DISEASE VACCINE]. / DISEÑO Y EVALUACIÓN DE UNA PROTEÍNA MULTIEPITÓPICA COMO CANDIDATA PARA VACUNA CONTRA LA ENFERMEDAD DE CARRIÓN.

OBJECTIVES.: To design and assess a multiepitopic protein as a candidate for a vaccine against Carrion disease. MATERIALS AND METHODS.: Using bioinformatics tools, epitopes of external membrane proteins were selected and a multiepitopic protein was designed. The multiepitopic protein gene was subcloned into the expression plasmid pET28b and transformed into E. coli BL21 pLys. The multiepitopic protein was expressed using isopropyl-ß-D-1-thiogalactopyranoside and purified using resin. This purified protein was used to immunize BALB/c mice obtaining polyclonal antibodies. In vitro invasion assays were conducted using a strain of Bartonella bacilliformis (B. bacilliformis) in human red blood cells. RESULTS.: The multiepitopic protein M1 presents preserved epitopes between isolates of B. bacilliformis with are non-toxic, and not homologous to human and surface proteins. Immunized mice presented IgG antibody levels capable of reducing in vitro the rate of invasion of B. bacilliformis into human red blood cells. CONCLUSIONS.: Multiepitopic protein M1 may serve as a candidate for a Carrion disease vaccine; however, more studies are needed to characterize the use of this antigen as a vaccine.

OBJETIVOS.: Diseñar y evaluar una proteína multiepítope como candidato a vacuna contra la enfermedad de Carrión. MATERIALES Y MÉTODOS.: Mediante herramientas bioinformáticas se seleccionó epítopes de proteínas de membrana externa y se diseñó una proteína multiepítope. El gen de la proteína multiepítope fue subclonado en el plásmido de expresión pET28b y transformado en E. coli BL21 pLys. La proteína multiepítope fue expresada usando isopropil-ß-D-1-tiogalactopiranósido y purificada usando resina. Esta proteína purificada fue utilizada para inmunizar ratones BALB/c y se obtuvo anticuerpos policlonales. Se realizaron ensayos de invasión in vitro usando una cepa de Bartonella bacilliformis (B. bacilliformis) a eritrocitos humanos. RESULTADOS.: La proteína multiepítope M1 presenta epítopes conservados entre aislamientos de B. bacilliformis, no tóxicos, no homólogos a proteínas humanas y superficiales. Los ratones inmunizados presentaron niveles de anticuerpos IgG capaces de reducir in vitro la tasa de invasión de B. bacilliformis a eritrocitos humanos. CONCLUSIONES.: La proteína multiepítope M1 podría servir como candidato a vacuna contra la enfermedad de Carrión; sin embargo, se requiere de más estudios para caracterizar el uso de este antígeno como vacuna.

Diseño y evaluación de una proteína multiepitópica como candidata para vacuna contra la enfermedad de carrión / Design and evaluation of a multiepitopic protein as a candidate for a carrion disease vaccine

RESUMEN Objetivos. Diseñar y evaluar una proteína multiepítope como candidato a vacuna contra la enfermedad de Carrión. Materiales y métodos. Mediante herramientas bioinformáticas se seleccionó epítopes de proteínas de membrana externa y se diseñó una proteína multiepítope. El gen de la proteína multiepítope fue subclonado en el plásmido de expresión pET28b y transformado en E. coli BL21 pLys. La proteína multiepítope fue expresada usando isopropil-β-D-1-tiogalactopiranósido y purificada usando resina. Esta proteína purificada fue utilizada para inmunizar ratones BALB/c y se obtuvo anticuerpos policlonales. Se realizaron ensayos de invasión in vitro usando una cepa de Bartonella bacilliformis (B. bacilliformis) a eritrocitos humanos. Resultados. La proteína multiepítope M1 presenta epítopes conservados entre aislamientos de B. bacilliformis, no tóxicos, no homólogos a proteínas humanas y superficiales. Los ratones inmunizados presentaron niveles de anticuerpos IgG capaces de reducir in vitro la tasa de invasión de B. bacilliformis a eritrocitos humanos. Conclusiones. La proteína multiepítope M1 podría servir como candidato a vacuna contra la enfermedad de Carrión; sin embargo, se requiere de más estudios para caracterizar el uso de este antígeno como vacuna.

ABSTRACT Objectives. To design and assess a multiepitopic protein as a candidate for a vaccine against Carrion disease. Materials and Methods. Using bioinformatics tools, epitopes of external membrane proteins were selected and a multiepitopic protein was designed. The multiepitopic protein gene was subcloned into the expression plasmid pET28b and transformed into E. coli BL21 pLys. The multiepitopic protein was expressed using isopropyl-β-D-1-thiogalactopyranoside and purified using resin. This purified protein was used to immunize BALB/c mice obtaining polyclonal antibodies. In vitro invasion assays were conducted using a strain of Bartonella bacilliformis (B. bacilliformis) in human red blood cells. Results. The multiepitopic protein M1 presents preserved epitopes between isolates of B. bacilliformis with are non-toxic, and not homologous to human and surface proteins. Immunized mice presented IgG antibody levels capable of reducing in vitro the rate of invasion of B. bacilliformis into human red blood cells. Conclusions. Multiepitopic protein M1 may serve as a candidate for a Carrion disease vaccine; however, more studies are needed to characterize the use of this antigen as a vaccine.