10 research outputs found
Development of Fluorescent Isocoumarin‐Fused Oxacyclononyne – 1,2,3‐Triazole Pairs
Fluorescent isocoumarin-fused cycloalkynes, which are reactive in SPAAC and give fluorescent triazoles regardless of the azide nature, have been developed. The key structural feature that converts the non-fluorescent cycloalkyne/triazole pair to its fluorescent counterpart is the pi-acceptor group (COOMe, CN) at the C6 position of the isocoumarin ring. The design of the fluorescent cycloalkyne/triazole pairs is based on the theoretical study of the S1 state deactivation mechanism of the non-fluorescent isocoumarin-fused cycloalkyne IC9O using multi-configurational ab initio and DFT methodologies. The calculations revealed that deactivation proceeds through the electrocyclic ring opening of the α-pyrone cycle and is accompanied by a redistribution of electron density in the fused benzene ring. We proposed that the S1 excited state deactivation barrier could be increased by introducing a pi-acceptor group into a position that is in direct conjugation with the formed C=O group and has a reduced electron density in the transition state. As a proof of concept, we designed and synthesized two fluorescent isocoumarin-fused cycloalkynes IC9O-COOMe and IC9O-CN bearing pi-acceptors at the C6 position. The importance of the nature of a pi-acceptor group was shown by the example of much less fluorescent CF-substituted cycloalkyne IC9O-CF
A Comparative Study of Modern Homology Modeling Algorithms for Rhodopsin Structure Prediction
Rhodopsins are seven α-helical membrane proteins that are of great importance in chemistry, biology, and modern biotechnology. Any in silico study on rhodopsin properties and functioning requires a high-quality three-dimensional structure. Due to particular difficulties with obtaining membrane protein structures from the experiment, in silico prediction of the three-dimensional rhodopsin structure based only on its primary sequence is an especially important task. For the last few years, significant progress was made in the field of protein structure prediction, especially for methods based on comparative modeling. However, the majority of this progress was made for soluble proteins and further investigations are needed to achieve similar progress for membrane proteins. In this paper, we evaluate the performance of modern protein structure prediction methodologies (implemented in the Medeller, I-TASSER, and Rosetta packages) for their ability to predict rhodopsin structures. Three widely used methodologies were considered: two general methodologies that are commonly applied to soluble proteins and a methodology that uses constraints that are specific for membrane proteins. The test pool consisted of 36 target-template pairs with different sequence similarities that was constructed on the basis of 24 experimental rhodopsin structures taken from the RCSB database. As a result, we showed that all three considered methodologies allow obtaining rhodopsin structures with the quality that is close to the crystallographic one (root mean square deviation (RMSD) of the predicted structure from the corresponding X-ray structure up to 1.5 Å) if the target-template sequence identity is higher than 40%. Moreover, all considered methodologies provided structures of average quality (RMSD < 4.0 Å) if the target-template sequence identity is higher than 20%. Such structures can be subsequently used for further investigation of molecular mechanisms of protein functioning and for the development of modern protein-based biotechnologies
Joint Activity of Autonomous Actors in an Open Educational Environment
Recently, a considerable literature has grown up around the theme of the transition to the digital economy, the increasing value of the individual with unique features and the ability for self-conscious activity. In order to improve the quality of teaching, it is necessary to develop a methodology of targeted application in the education of jointly distributed activities, characteristic of modern youth.In this regard, this article aims at the development of the assessment criteria and identification of actor’s autonomy levels and their joint activities in the educational process, and definition of methods for organizing jointly distributed activities of autonomous actors in the education.The leading methods in the study were monitoring the activities of teachers and students in social networks, especially on educational communication platforms, identifying and comparing the characteristics of these activities; analysis of the products of educational activities of students interacting in educational networks; expert assessments to determine the level of quality of the achieved results.The article justifies the criteria of assessment of the levels of the educational actors’ autonomy and their activities, developed the methods of organizing jointly distributed activities of autonomous actors of the educational process and revealed the possibility of changing their functional roles depending on the type of their interaction.The materials presented in the article allow creating the organizational and methodological conditions for the formation of virtual training groups, taking into account the level of preparedness of autonomous actors for joint educational activities in order to improve the quality of teaching
Fluorescence Imaging of Cell Membrane Potential: From Relative Changes to Absolute Values
Membrane potential is a fundamental property of biological cells. Changes in membrane potential characterize a vast number of vital biological processes, such as the activity of neurons and cardiomyocytes, tumorogenesis, cell-cycle progression, etc. A common strategy to record membrane potential changes that occur in the process of interest is to utilize organic dyes or genetically-encoded voltage indicators with voltage-dependent fluorescence. Sensors are introduced into target cells, and alterations of fluorescence intensity are recorded with optical methods. Techniques that allow recording relative changes of membrane potential and do not take into account fluorescence alterations due to factors other than membrane voltage are already widely used in modern biological and biomedical studies. Such techniques have been reviewed previously in many works. However, in order to investigate a number of processes, especially long-term processes, the measured signal must be corrected to exclude the contribution from voltage-independent factors or even absolute values of cell membrane potential have to be evaluated. Techniques that enable such measurements are the subject of this review
Fluorescence Imaging of Cell Membrane Potential: From Relative Changes to Absolute Values
Membrane potential is a fundamental property of biological cells. Changes in membrane potential characterize a vast number of vital biological processes, such as the activity of neurons and cardiomyocytes, tumorogenesis, cell-cycle progression, etc. A common strategy to record membrane potential changes that occur in the process of interest is to utilize organic dyes or genetically-encoded voltage indicators with voltage-dependent fluorescence. Sensors are introduced into target cells, and alterations of fluorescence intensity are recorded with optical methods. Techniques that allow recording relative changes of membrane potential and do not take into account fluorescence alterations due to factors other than membrane voltage are already widely used in modern biological and biomedical studies. Such techniques have been reviewed previously in many works. However, in order to investigate a number of processes, especially long-term processes, the measured signal must be corrected to exclude the contribution from voltage-independent factors or even absolute values of cell membrane potential have to be evaluated. Techniques that enable such measurements are the subject of this review
A Comparative Study of Modern Homology Modeling Algorithms for Rhodopsin Structure Prediction
Rhodopsins
are seven α-helical membrane proteins that are
of great importance in chemistry, biology, and modern biotechnology.
Any in silico study on rhodopsin properties and functioning requires
a high-quality three-dimensional structure. Due to particular difficulties
with obtaining membrane protein structures from the experiment, in
silico prediction of the three-dimensional rhodopsin structure based
only on its primary sequence is an especially important task. For
the last few years, significant progress was made in the field of
protein structure prediction, especially for methods based on comparative
modeling. However, the majority of this progress was made for soluble
proteins and further investigations are needed to achieve similar
progress for membrane proteins. In this paper, we evaluate the performance
of modern protein structure prediction methodologies (implemented
in the Medeller, I-TASSER, and Rosetta packages) for their ability
to predict rhodopsin structures. Three widely used methodologies were
considered: two general methodologies that are commonly applied to
soluble proteins and a methodology that uses constraints that are
specific for membrane proteins. The test pool consisted of 36 target-template
pairs with different sequence similarities that was constructed on
the basis of 24 experimental rhodopsin structures taken from the RCSB
database. As a result, we showed that all three considered methodologies
allow obtaining rhodopsin structures with the quality that is close
to the crystallographic one (root mean square deviation (RMSD) of
the predicted structure from the corresponding X-ray structure up
to 1.5 Å) if the target-template sequence identity is higher
than 40%. Moreover, all considered methodologies provided structures
of average quality (RMSD < 4.0 Å) if the target-template sequence
identity is higher than 20%. Such structures can be subsequently used
for further investigation of molecular mechanisms of protein functioning
and for the development of modern protein-based biotechnologies
A Comparative Study of Modern Homology Modeling Algorithms for Rhodopsin Structure Prediction
Rhodopsins
are seven α-helical membrane proteins that are
of great importance in chemistry, biology, and modern biotechnology.
Any in silico study on rhodopsin properties and functioning requires
a high-quality three-dimensional structure. Due to particular difficulties
with obtaining membrane protein structures from the experiment, in
silico prediction of the three-dimensional rhodopsin structure based
only on its primary sequence is an especially important task. For
the last few years, significant progress was made in the field of
protein structure prediction, especially for methods based on comparative
modeling. However, the majority of this progress was made for soluble
proteins and further investigations are needed to achieve similar
progress for membrane proteins. In this paper, we evaluate the performance
of modern protein structure prediction methodologies (implemented
in the Medeller, I-TASSER, and Rosetta packages) for their ability
to predict rhodopsin structures. Three widely used methodologies were
considered: two general methodologies that are commonly applied to
soluble proteins and a methodology that uses constraints that are
specific for membrane proteins. The test pool consisted of 36 target-template
pairs with different sequence similarities that was constructed on
the basis of 24 experimental rhodopsin structures taken from the RCSB
database. As a result, we showed that all three considered methodologies
allow obtaining rhodopsin structures with the quality that is close
to the crystallographic one (root mean square deviation (RMSD) of
the predicted structure from the corresponding X-ray structure up
to 1.5 Å) if the target-template sequence identity is higher
than 40%. Moreover, all considered methodologies provided structures
of average quality (RMSD < 4.0 Å) if the target-template sequence
identity is higher than 20%. Such structures can be subsequently used
for further investigation of molecular mechanisms of protein functioning
and for the development of modern protein-based biotechnologies