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The CUET PG 2024 Life Sciences Question Paper (SCQP17) and its solution PDF are available for download, along with the question papers from previous years (2023, 2022, and 2021). Shift-wise papers from 2023, including answer keys for different exam dates and language options, are also available.
The CUET PG 2024 Life Sciences exam had a new format, reducing the total number of questions from 100 to 75 by removing the General Test (Part A). Each exam lasted 105 minutes and had a maximum score of 300 marks. Based on previous years' papers, an estimated topic-wise weightage for the CUET PG 2025 Life Sciences exam (SCQP17) is also provided for reference.
| CUET PG Year Wise Question Paper Download | |
|---|---|
| CUET PG 2025 Question Paper | CUET PG 2024 Question Paper |
| CUET PG 2023 Question Paper | CUET PG 2022 Question Paper |
| Subject | Question Paper | Solution PDF |
|---|---|---|
| Life Sciences | Download | Check Solutions |
CUET PG Life Sciences Previous Years’ Question Paper (2023-2022)
The previous years’ question paper (2023-2022) of CUET PG Life Sciences is provided here.
CUET PG Life Science Question Paper 2023
| Paper/Subject | Question Paper PDF |
|---|---|
| Life Sciences | Download |
CUET PG Life Sciences Question Paper 2022
| Subject | Question Paper PDF Link |
|---|---|
| Life Sciences | Download |
CUET PG Life Sciences Question Paper 2021
| Paper/Subject | Question Paper Link |
|---|---|
| PGQP22 | Download |
Expected Topic-wise Weightage for CUET PG 2025 (Life Sciences- SCQP17)
The expected topic-wise weightage for CUET PG 2025 (Life Sciences - SCQP17) is based on the observed trends from the CUET PG 2024 Life Sciences Question Paper. Here is an estimate of how different topics are likely to be weighted in the upcoming exam:
Detailed Sub-topic-wise Weightage for CUET PG 2025 (Life Sciences - SCQP17)
| Major Topics | Sub-Topics | Expected Weightage (%) |
|---|---|---|
| Techniques | Principles and applications of chromatography, spectroscopy, microscopy, electrophoresis, centrifugation, blotting, PCR, Radioisotope Techniques | 10.0% |
| Chromatin Structure and Function | Organization of chromosomes in prokaryotes and eukaryotes | 3.0% |
| Chromatin types | 2.0% | |
| Centromere | 1.0% | |
| Telomere | 1.0% | |
| Concept of Gene | 1.3% | |
| Biochemistry | Structure and functions of proteins, DNA, Carbohydrates, Lipids & Vitamins | 7.5% |
| Bioenergetics | 2.5% | |
| Glycolysis | 1.5% | |
| TCA Cycle | 1.0% | |
| Electron Transport Chain | 1.0% | |
| ATP Synthesis | 1.5% | |
| Oxidation and Synthesis of Fatty Acids | 1.0% | |
| Membrane Structure and Function | 2.0% | |
| Biotechnology | Recombinant DNA technology, Gene Cloning | 4.0% |
| Applications in Medicine, Industry, Agriculture | 4.0% | |
| Animal & Plant Cell Culture | 2.5% | |
| Environmental Biotechnology | 2.5% | |
| Microbiology | Microbial Diversity, Bacterial Reproduction | 3.0% |
| Antimicrobial Agents | 2.0% | |
| Significance of Microbes in Industry and Agriculture | 2.0% | |
| Antigen, Antibody, Complement Systems | 2.0% | |
| Immunity | 2.0% | |
| Vaccines | 1.5% | |
| Plant Virus, Animal Virus | 1.5% | |
| Environmental Microbiology | 1.4% | |
| Molecular Genetics | Principles of Inheritance | 2.5% |
| Linkage & Crossing Over | 2.0% | |
| Chromosomal Aberrations | 2.0% | |
| Extrachromosomal Inheritance | 2.0% | |
| Replication | 1.7% | |
| Transcription | 1.7% | |
| Translation | 1.5% | |
| DNA Repair | 1.5% | |
| Population Genetics | 2.0% | |
| Plant Sciences | Bryophytes | 2.0% |
| Pteridophytes | 2.0% | |
| Gymnosperms | 2.0% | |
| Angiosperms | 2.5% | |
| Vascular System in Plants | 1.5% | |
| Economic Importance of Plants | 1.0% | |
| Photosynthesis | 2.0% | |
| Photoperiodism & Vernalization | 1.0% | |
| Biogeochemical Cycle | 1.1% | |
| Animal Sciences | Characteristics of Invertebrates and Vertebrates | 2.5% |
| Anatomy and Physiology of Human Systems | 3.0% | |
| Nerve Impulse Transmission | 1.5% | |
| Endocrinology | 1.5% | |
| Human Diseases | 1.0% | |
| Apoptosis & Cancer | 1.0% | |
| Inherited Diseases | 0.8% | |
| Animal Cell Culture | 0.8% |
Expected Topic-Wise Weightage for CUET PG Life Sciences Paper 2025
CUET PG Life Sciences Question Paper Analysis (2024-2023)
The CUET PG 2023 Life Sciences exam was largely based on factual recall and straightforward application of concepts, requiring students to recall biological processes and apply them in direct situations. However, in 2024, the focus shifted towards analysis and application-based questions, where students were asked to interpret data, compare experimental results, and apply theoretical concepts to real-world biological problems.
The 2024 paper had more questions that required critical thinking, particularly in areas such as Genetics, Biochemistry, Microbiology, and Human Physiology. Students were expected to interpret experimental data, analyze molecular processes, and evaluate the practical implications of biological phenomena, making the exam more analytical and conceptual in nature.
CUET PG 2023 vs. CUET PG 2024 Life Sciences Topics Comparison
| Topic Category | CUET PG 2023 Topics | CUET PG 2024 Topics |
|---|---|---|
| Biochemistry | Direct factual recall on metabolic pathways | Data interpretation, enzyme kinetics, and energy metabolism analysis |
| Genetics | Basic inheritance patterns, Mendelian genetics | In-depth analysis of genetic variations, gene expression, and molecular genetics |
| Microbiology | Identification of microorganisms and basic concepts | More analytical, focused on microbial interactions, and real-world applications of microbiology |
| Plant Biology | Basic knowledge of plant structures and functions | More focus on plant biochemistry, cellular biology, and plant genetics |
| Human Physiology | Basic physiological concepts | Application-based, such as interpreting data on homeostasis or disease mechanisms |
Biochemistry: In 2024, the exam focused more on analyzing data than just remembering metabolic pathways and enzyme functions. Students had to understand data on enzyme activity, energy production, and cell functions, predict results, and connect these ideas to real-life examples.
Genetics and Molecular Biology: The exam's focus shifted from basic genetics to more challenging topics such as gene regulation, DNA repair, and genetic changes. There were questions about gene therapy and CRISPR technology, and students had to apply what they learned to real-world situations.
Microbiology: The focus was on real-world problems like antibiotic resistance, microbe genetics, and biotechnology. Students needed to understand how microbes grow, interact, and resist treatments based on experiment data.
Plant Biology: Instead of basic plant genetics, the exam covered gene control, DNA repair, and genetic changes. Questions on gene therapy and CRISPR technology required students to apply these ideas to real-world examples.
Human Physiology and Biochemistry: The exam tested both biochemistry and physiology. Students had to understand how hormones, energy pathways, and genetic diseases affect human health and be able to analyze related data.
*The article might have information for the previous academic years, which will be updated soon subject to the notification issued by the University/College.
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