| File | Title | Manuscript Id |
|---|
| Chapter 13 Introduction | morris2e_ch13_1.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_1_dlap.xml | 5612a66a757a2e9c58000000 |
| 13.1 Genome Sequencing
| morris2e_ch13_2.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_2_dlap.xml | 5612a66a757a2e9c58000000 |
| Complete genome sequences are assembled from smaller pieces.
| morris2e_ch13_3.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_3_dlap.xml | 5612a66a757a2e9c58000000 |
| Sequences that are repeated complicate sequence assembly.
| morris2e_ch13_4.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_4_dlap.xml | 5612a66a757a2e9c58000000 |
| Case 3: Why sequence your personal genome?
| morris2e_ch13_5.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_5_dlap.xml | 5612a66a757a2e9c58000000 |
| 13.2 Genome Annotation
| morris2e_ch13_6.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_6_dlap.xml | 5612a66a757a2e9c58000000 |
| Genome annotation identifies various types of sequence.
| morris2e_ch13_7.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_7_dlap.xml | 5612a66a757a2e9c58000000 |
| Genome annotation includes searching for sequence motifs.
| morris2e_ch13_8.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_8_dlap.xml | 5612a66a757a2e9c58000000 |
| Comparison of genomic DNA with messenger RNA reveals the intron–exon structure of genes.
| morris2e_ch13_9.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_9_dlap.xml | 5612a66a757a2e9c58000000 |
| An annotated genome summarizes knowledge, guides research, and reveals evolutionary relationships among organisms.
| morris2e_ch13_10.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_10_dlap.xml | 5612a66a757a2e9c58000000 |
| The HIV genome illustrates the utility of genome annotation and comparison.
| morris2e_ch13_11.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_11_dlap.xml | 5612a66a757a2e9c58000000 |
| 13.3 Gene Number, Genome Size, and Organismal Complexity
| morris2e_ch13_12.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_12_dlap.xml | 5612a66a757a2e9c58000000 |
| Gene number is not a good predictor of biological complexity.
| morris2e_ch13_13.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_13_dlap.xml | 5612a66a757a2e9c58000000 |
| Viruses, bacteria, and archaeons have small, compact genomes.
| morris2e_ch13_14.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_14_dlap.xml | 5612a66a757a2e9c58000000 |
| Among eukaryotes, there is no relationship between genome size and organismal complexity.
| morris2e_ch13_15.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_15_dlap.xml | 5612a66a757a2e9c58000000 |
| About half of the human genome consists of transposable elements and other types of repetitive DNA.
| morris2e_ch13_16.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_16_dlap.xml | 5612a66a757a2e9c58000000 |
| 13.4 Organization of Genomes
| morris2e_ch13_17.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_17_dlap.xml | 5612a66a757a2e9c58000000 |
| Bacterial cells package their DNA as a nucleoid composed of many loops.
| morris2e_ch13_18.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_18_dlap.xml | 5612a66a757a2e9c58000000 |
| Eukaryotic cells package their DNA as one molecule per chromosome.
| morris2e_ch13_19.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_19_dlap.xml | 5612a66a757a2e9c58000000 |
| The human genome consists of 22 pairs of chromosomes and two sex chromosomes.
| morris2e_ch13_20.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_20_dlap.xml | 5612a66a757a2e9c58000000 |
| Organelle DNA forms nucleoids that differ from those in bacteria.
| morris2e_ch13_21.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_21_dlap.xml | 5612a66a757a2e9c58000000 |
| 13.5 Viruses and Viral Genomes
| morris2e_ch13_22.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_22_dlap.xml | 5612a66a757a2e9c58000000 |
| Viruses can be classified by their genomes.
| morris2e_ch13_23.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_23_dlap.xml | 5612a66a757a2e9c58000000 |
| The host range of a virus is determined by viral and host surface proteins.
| morris2e_ch13_24.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_24_dlap.xml | 5612a66a757a2e9c58000000 |
| Viruses have diverse sizes and shapes.
| morris2e_ch13_25.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_25_dlap.xml | 5612a66a757a2e9c58000000 |
| Viruses are capable of self-assembly.
| morris2e_ch13_26.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_26_dlap.xml | 5612a66a757a2e9c58000000 |
| Chapter 13 Summary | morris2e_ch13_27.html | 5612a66a757a2e9c58000000 |
| DLAP questions | morris2e_ch13_27_dlap.xml | 5612a66a757a2e9c58000000 |