So now that we've covered covalent bonds in our previous lesson videos, in this video we're going to introduce non covalent bonds. Non-covalent bonds are really just defined as interactions between two atoms resulting from full or partial charges. Now, unlike the covalent bonds that we talked about in our previous lesson videos, when it comes to non-covalent bonds, there's absolutely no sharing of electrons. And so recall from our previous lesson videos that the word covalent is referring to the sharing of electrons. But if we add the non in front of the covalent, of course, that means no sharing of electrons. So that's an important distinction between the covalent and the non-covalent bonds. Now there are several different types of non-covalent bonds that are common in biology. Moving forward in our course, we're going to talk about some of these different types of non-covalent bonds, and you can see that here we're showing you a table of some of the different types of non-covalent bonds. And really, they can be broken up into two major groups. There are strong electrostatic interactions, and then there are weak Van Der Waals interactions. Now for our biology course, we're not really going to talk a lot about the weak Van Der Waals interactions. You'll get to learn more about the weak Van Der Waals interactions in your chemistry courses. But for our biology course moving forward, we're going to focus our attention mainly on the strong electrostatic interactions, and really there are two different types that you should be aware of. There are ionic bonds, and then there are hydrogen bonds. And so if we take a look at the table, the map that we have down below, you'll see that this table corresponds really nicely with the map. And so once again here is the map of our lesson on chemical bonds and we know, already in our previous lesson videos we've been following this map, following the leftmost branches first. So already in our previous lesson videos, we've talked about covalent bonds including non-polar covalent and polar covalent bonds. So here in this video, we're starting to talk about this other branch here, the non-covalent bonds. And as we've mentioned already, they can be broken up into two major groups, the strong electrostatic interactions and then the weak Van der Waals interactions, like this weak little guy over here. Now once again, the weak Van der Waals interactions, we're not really going to talk about, in our course moving forward. You'll get to learn more about the weak Van Der Waals interactions when you take your chemistry course. But for our biology course, we're mainly going to focus on these strong electrostatic interactions, which include the ionic bonds and the hydrogen bonds. And so we'll get to talk more about the ionic and hydrogen bonds moving forward in our course. We'll start off with the ionic bonds and then after talking about those, we'll move on to talking about the hydrogen bonds. So that being said, I'll see you all in our next video.
- 1. Introduction to Microbiology3h 21m
- Introduction to Microbiology16m
- Introduction to Taxonomy26m
- Scientific Naming of Organisms9m
- Members of the Bacterial World10m
- Introduction to Bacteria9m
- Introduction to Archaea10m
- Introduction to Eukarya20m
- Acellular Infectious Agents: Viruses, Viroids & Prions19m
- Importance of Microorganisms20m
- Scientific Method27m
- Experimental Design30m
- 2. Disproving Spontaneous Generation1h 18m
- 3. Chemical Principles of Microbiology3h 38m
- 4. Water1h 28m
- 5. Molecules of Microbiology2h 23m
- 6. Cell Membrane & Transport3h 28m
- Cell Envelope & Biological Membranes12m
- Bacterial & Eukaryotic Cell Membranes8m
- Archaeal Cell Membranes18m
- Types of Membrane Proteins8m
- Concentration Gradients and Diffusion9m
- Introduction to Membrane Transport14m
- Passive vs. Active Transport13m
- Osmosis33m
- Simple and Facilitated Diffusion17m
- Active Transport30m
- ABC Transporters11m
- Group Translocation7m
- Types of Small Molecule Transport Review9m
- Endocytosis and Exocytosis15m
- 7. Prokaryotic Cell Structures & Functions5h 52m
- Prokaryotic & Eukaryotic Cells26m
- Binary Fission11m
- Generation Times16m
- Bacterial Cell Morphology & Arrangements35m
- Overview of Prokaryotic Cell Structure10m
- Introduction to Bacterial Cell Walls26m
- Gram-Positive Cell Walls11m
- Gram-Negative Cell Walls20m
- Gram-Positive vs. Gram-Negative Cell Walls11m
- The Glycocalyx: Capsules & Slime Layers12m
- Introduction to Biofilms6m
- Pili18m
- Fimbriae & Hami7m
- Introduction to Prokaryotic Flagella12m
- Prokaryotic Flagellar Structure18m
- Prokaryotic Flagellar Movement11m
- Proton Motive Force Drives Flagellar Motility5m
- Chemotaxis14m
- Review of Prokaryotic Surface Structures8m
- Prokaryotic Ribosomes16m
- Introduction to Bacterial Plasmids13m
- Cell Inclusions9m
- Endospores16m
- Sporulation5m
- Germination5m
- 8. Eukaryotic Cell Structures & Functions2h 18m
- 9. Microscopes2h 46m
- Introduction to Microscopes8m
- Magnification, Resolution, & Contrast10m
- Introduction to Light Microscopy5m
- Light Microscopy: Bright-Field Microscopes23m
- Light Microscopes that Increase Contrast16m
- Light Microscopes that Detect Fluorescence16m
- Electron Microscopes14m
- Reviewing the Different Types of Microscopes10m
- Introduction to Staining5m
- Simple Staining14m
- Differential Staining6m
- Other Types of Staining11m
- Reviewing the Types of Staining8m
- Gram Stain13m
- 10. Dynamics of Microbial Growth4h 36m
- Biofilms16m
- Growing a Pure Culture5m
- Microbial Growth Curves in a Closed System21m
- Temperature Requirements for Microbial Growth18m
- Oxygen Requirements for Microbial Growth22m
- pH Requirements for Microbial Growth8m
- Osmolarity Factors for Microbial Growth14m
- Reviewing the Environmental Factors of Microbial Growth12m
- Nutritional Factors of Microbial Growth30m
- Growth Factors4m
- Introduction to Cultivating Microbial Growth5m
- Types of Solid Culture Media4m
- Plating Methods16m
- Measuring Growth by Direct Cell Counts9m
- Measuring Growth by Plate Counts14m
- Measuring Growth by Membrane Filtration6m
- Measuring Growth by Biomass15m
- Introduction to the Types of Culture Media5m
- Chemically Defined Media3m
- Complex Media4m
- Selective Media5m
- Differential Media9m
- Reducing Media4m
- Enrichment Media7m
- Reviewing the Types of Culture Media8m
- 11. Controlling Microbial Growth4h 10m
- Introduction to Controlling Microbial Growth29m
- Selecting a Method to Control Microbial Growth44m
- Physical Methods to Control Microbial Growth49m
- Review of Physical Methods to Control Microbial Growth7m
- Chemical Methods to Control Microbial Growth16m
- Chemicals Used to Control Microbial Growth6m
- Liquid Chemicals: Alcohols, Aldehydes, & Biguanides15m
- Liquid Chemicals: Halogens12m
- Liquid Chemicals: Surface-Active Agents17m
- Other Types of Liquid Chemicals14m
- Chemical Gases: Ethylene Oxide, Ozone, & Formaldehyde13m
- Review of Chemicals Used to Control Microbial Growth11m
- Chemical Preservation of Perishable Products10m
- 12. Microbial Metabolism5h 16m
- Introduction to Energy15m
- Laws of Thermodynamics15m
- Chemical Reactions9m
- ATP20m
- Enzymes14m
- Enzyme Activation Energy9m
- Enzyme Binding Factors9m
- Enzyme Inhibition10m
- Introduction to Metabolism8m
- Negative & Positive Feedback7m
- Redox Reactions22m
- Introduction to Aerobic Cellular Respiration25m
- Types of Phosphorylation12m
- Glycolysis19m
- Entner-Doudoroff Pathway11m
- Pentose-Phosphate Pathway10m
- Pyruvate Oxidation8m
- Krebs Cycle16m
- Electron Transport Chain19m
- Chemiosmosis7m
- Review of Aerobic Cellular Respiration19m
- Fermentation & Anaerobic Respiration23m
- 13. Photosynthesis2h 31m
- 14. DNA Replication2h 25m
- 15. Central Dogma & Gene Regulation7h 14m
- Central Dogma7m
- Introduction to Transcription20m
- Steps of Transcription22m
- Transcription Termination in Prokaryotes7m
- Eukaryotic RNA Processing and Splicing20m
- Introduction to Types of RNA9m
- Genetic Code25m
- Introduction to Translation30m
- Steps of Translation23m
- Review of Transcription vs. Translation12m
- Prokaryotic Gene Expression21m
- Review of Prokaryotic vs. Eukaryotic Gene Expression13m
- Introduction to Regulation of Gene Expression13m
- Prokaryotic Gene Regulation via Operons27m
- The Lac Operon21m
- Glucose's Impact on Lac Operon25m
- The Trp Operon20m
- Review of the Lac Operon & Trp Operon11m
- Introduction to Eukaryotic Gene Regulation9m
- Eukaryotic Chromatin Modifications16m
- Eukaryotic Transcriptional Control22m
- Eukaryotic Post-Transcriptional Regulation28m
- Post-Translational Modification6m
- Eukaryotic Post-Translational Regulation13m
- 16. Microbial Genetics4h 44m
- Introduction to Microbial Genetics11m
- Introduction to Mutations20m
- Methods of Inducing Mutations15m
- Prototrophs vs. Auxotrophs13m
- Mutant Detection25m
- The Ames Test14m
- Introduction to DNA Repair5m
- DNA Repair Mechanisms37m
- Horizontal Gene Transfer18m
- Bacterial Transformation11m
- Transduction32m
- Introduction to Conjugation6m
- Conjugation: F Plasmids18m
- Conjugation: Hfr & F' Cells19m
- Genome Variability21m
- CRISPR CAS11m
- 17. Biotechnology3h 0m
- 18. Viruses, Viroids, & Prions4h 56m
- Introduction to Viruses20m
- Introduction to Bacteriophage Infections14m
- Bacteriophage: Lytic Phage Infections12m
- Bacteriophage: Lysogenic Phage Infections17m
- Bacteriophage: Filamentous Phage Infections8m
- Plaque Assays9m
- Introduction to Animal Virus Infections10m
- Animal Viruses: 1. Attachment to the Host Cell7m
- Animal Viruses: 2. Entry & Uncoating in the Host Cell19m
- Animal Viruses: 3. Synthesis & Replication22m
- Animal Viruses: DNA Virus Synthesis & Replication14m
- Animal Viruses: RNA Virus Synthesis & Replication22m
- Animal Viruses: Antigenic Drift vs. Antigenic Shift9m
- Animal Viruses: Reverse-Transcribing Virus Synthesis & Replication9m
- Animal Viruses: 4. Assembly Inside Host Cell8m
- Animal Viruses: 5. Release from Host Cell15m
- Acute vs. Persistent Viral Infections25m
- COVID-19 (SARS-CoV-2)14m
- Plant Viruses12m
- Viroids6m
- Prions13m
- 19. Innate Immunity7h 15m
- Introduction to Immunity8m
- Introduction to Innate Immunity17m
- Introduction to First-Line Defenses5m
- Physical Barriers in First-Line Defenses: Skin13m
- Physical Barriers in First-Line Defenses: Mucous Membrane9m
- First-Line Defenses: Chemical Barriers24m
- First-Line Defenses: Normal Microflora5m
- Introduction to Cells of the Immune System15m
- Cells of the Immune System: Granulocytes29m
- Cells of the Immune System: Agranulocytes25m
- Introduction to Cell Communication5m
- Cell Communication: Surface Receptors & Adhesion Molecules16m
- Cell Communication: Cytokines27m
- Pattern Recognition Receptors (PRRs)45m
- Introduction to the Complement System24m
- Activation Pathways of the Complement System23m
- Effects of the Complement System23m
- Review of the Complement System12m
- Phagoctytosis21m
- Introduction to Inflammation18m
- Steps of the Inflammatory Response26m
- Fever8m
- Interferon Response25m
- 20. Adaptive Immunity7h 14m
- Introduction to Adaptive Immunity32m
- Antigens12m
- Introduction to T Lymphocytes38m
- Major Histocompatibility Complex Molecules20m
- Activation of T Lymphocytes21m
- Functions of T Lymphocytes25m
- Review of Cytotoxic vs Helper T Cells13m
- Introduction to B Lymphocytes27m
- Antibodies14m
- Classes of Antibodies35m
- Outcomes of Antibody Binding to Antigen15m
- T Dependent & T Independent Antigens21m
- Clonal Selection20m
- Antibody Class Switching17m
- Affinity Maturation14m
- Primary and Secondary Response of Adaptive Immunity21m
- Immune Tolerance28m
- Regulatory T Cells10m
- Natural Killer Cells16m
- Review of Adaptive Immunity25m
- 21. Principles of Disease6h 57m
- Symbiotic Relationships12m
- The Human Microbiome46m
- Characteristics of Infectious Disease47m
- Stages of Infectious Disease Progression26m
- Koch's Postulates26m
- Molecular Koch's Postulates11m
- Bacterial Pathogenesis36m
- Introduction to Pathogenic Toxins6m
- Exotoxins Cause Damage to the Host40m
- Endotoxin Causes Damage to the Host13m
- Exotoxins vs. Endotoxin Review13m
- Immune Response Damage to the Host15m
- Introduction to Avoiding Host Defense Mechanisms8m
- 1) Hide Within Host Cells5m
- 2) Avoiding Phagocytosis31m
- 3) Surviving Inside Phagocytic Cells10m
- 4) Avoiding Complement System9m
- 5) Avoiding Antibodies25m
- Viruses Evade the Immune Response27m
Noncovalent Bonds - Online Tutor, Practice Problems & Exam Prep
Non-covalent bonds are interactions between atoms that arise from full or partial charges, without sharing electrons. They are categorized into strong electrostatic interactions, such as ionic bonds and hydrogen bonds, and weak Van der Waals interactions. In biological contexts, ionic and hydrogen bonds play crucial roles in molecular stability and interactions, influencing processes like enzyme activity and molecular recognition. Understanding these bonds is essential for grasping the complexities of biological systems and their functions.
Noncovalent Bonds
Video transcript
Which of the following are considered to be very weak non-covalent chemical bonds?
Do you want more practice?
Here’s what students ask on this topic:
What are non-covalent bonds and how do they differ from covalent bonds?
Non-covalent bonds are interactions between atoms that arise from full or partial charges, without sharing electrons. In contrast, covalent bonds involve the sharing of electrons between atoms. Non-covalent bonds can be categorized into strong electrostatic interactions, such as ionic bonds and hydrogen bonds, and weak Van der Waals interactions. Covalent bonds are generally stronger and more stable than non-covalent bonds. Non-covalent bonds play crucial roles in biological systems, influencing processes like enzyme activity and molecular recognition, while covalent bonds are essential for forming the stable structures of molecules.
What are the different types of non-covalent bonds?
Non-covalent bonds can be categorized into two major groups: strong electrostatic interactions and weak Van der Waals interactions. Strong electrostatic interactions include ionic bonds and hydrogen bonds. Ionic bonds occur between atoms with full opposite charges, while hydrogen bonds form between a hydrogen atom covalently bonded to an electronegative atom (like oxygen or nitrogen) and another electronegative atom. Weak Van der Waals interactions include dipole-dipole interactions, London dispersion forces, and induced dipole interactions. In biological contexts, ionic and hydrogen bonds are particularly important for molecular stability and interactions.
Why are hydrogen bonds important in biological systems?
Hydrogen bonds are crucial in biological systems because they contribute to the stability and functionality of biomolecules. For example, hydrogen bonds play a key role in maintaining the structure of DNA by holding the two strands together. They also stabilize the secondary and tertiary structures of proteins, influencing their shape and function. Additionally, hydrogen bonds are involved in enzyme-substrate interactions, affecting enzyme activity and specificity. Overall, hydrogen bonds are essential for the proper functioning of biological molecules and processes.
How do ionic bonds contribute to molecular interactions in biology?
Ionic bonds contribute to molecular interactions in biology by providing strong electrostatic attractions between oppositely charged ions. These bonds are crucial for the stability of many biological structures, such as the formation of salt bridges in proteins, which help maintain their three-dimensional structure. Ionic bonds also play a role in the binding of substrates to enzymes, influencing enzyme activity and specificity. Additionally, they are involved in the formation of complexes between biomolecules, facilitating processes like signal transduction and molecular recognition.
What are Van der Waals interactions and why are they considered weak?
Van der Waals interactions are weak, non-covalent forces that arise from temporary fluctuations in electron distribution, leading to transient dipoles. These interactions include dipole-dipole interactions, London dispersion forces, and induced dipole interactions. They are considered weak because the forces involved are much smaller compared to covalent or ionic bonds. Despite their weakness, Van der Waals interactions are important in biological systems, contributing to the overall stability and specificity of molecular interactions, such as the binding of ligands to proteins and the packing of lipid bilayers in cell membranes.